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From Conventional to
Microphotochemistry: A study of Phthalimide and Phthalonitrile
derivatives
PhD Thesis
Sonia Gallagher (B.Sc) April 2011
The School of Chemical Sciences
Dublin City University
Supervisors: Dr. Michael Oelgemöller
Dr. Kieran Nolan
ii
I hereby certify that this material, which I now submit for assessment on the
programme of study leading to the award of Doctor of Philosophy is entirely
my own work, that I have exercised reasonable care to ensure that the work is
original, and does not to the best of my knowledge breach any law of
copyright, and has not been taken from the work of others save and to the
extent that such work has been cited and acknowledged within the text of my
work.
Signed: ____________________________ ID No.: 52001047
Date: ____________________________
iii
Table of Contents Acknowledgements ix
List of abbreviations x
Abstract xii
1 Literature review 2
1.1 Photochemistry............................................................................................. 2
1.1.1 Photoinduced Electron Transfer (PET)....................................................... 4
1.2 Introduction to phthalimides ...................................................................... 5
1.2.1 Pharmaceutical and industrial importance of phthalimides ........................ 5
1.2.2 Phthalimides in organic synthesis ............................................................... 7
1.2.3 Photophysical and electrochemical properties of phthalimides .................. 8
1.3 Photoaddition reactions involving phthalimides....................................... 9
1.3.1 Photoadditions of arenes ............................................................................. 9
1.3.2 Photoadditions of alkenes ........................................................................... 9
1.3.2.1 Photoreductions 11
1.3.3 Photoadditions of oxygen containing compounds .................................... 12
1.3.3.1 Photoadditions of ethers 12
1.3.3.2 Photoadditions of α-trialkylsilylmethyl-substituted ethers 13
1.3.4 Photoadditions of nitrogen containing compounds................................... 13
1.3.4.1 Photoadditions of amines 13
1.3.4.2 Photoadditions of α-trialkylsilylmethyl-substituted amines 14
1.3.5 Photoadditions of sulfur containing compounds....................................... 15
1.3.5.1 Photoadditions of thioethers 15
1.3.5.2 Photoadditions of α-trialkylsilylmethyl-substituted thioethers 15
1.3.6 Photoadditions of carboxylates ................................................................. 16
1.3.6.1 Photoadditions of alkyl carboxylates 16
1.3.6.2 Photoadditions of heteroatom substituted carboxylates 17
1.3.6.3 Intramolecular decarboxylative cyclisation reactions 19
1.4 Aristolactams.............................................................................................. 19
1.4.1 Naturally occurring aristolactams and their biological activity ................ 19
1.4.1.1 Examples of related derivatives 21
1.4.1.2 Isolation of natural aristolactams 22
1.4.2 Synthesis of aristolactams ......................................................................... 23
iv
1.5 Phthalonitriles and phthalocyanines ........................................................ 25
1.5.1 General structure and properties ............................................................... 25
1.5.2 Photodynamic therapy and phthalocyanines............................................. 26
1.5.3 Synthesis of phthalocyanines .................................................................... 27
1.5.4 Solubility of phthalocyanines.................................................................... 29
1.5.5 Sulfonated phthalocyanines ...................................................................... 30
1.6 Microphotochemistry................................................................................. 35
1.6.1 Examples of microstructured reactors....................................................... 35
1.6.2 Selected examples of micro-photochemical reactions .............................. 38
Thesis proposal 41
2 Photoaddition reactions of NMP and phthalimide 44
2.1 Introduction................................................................................................ 44
2.2 Synthesis of starting material.................................................................... 45
2.2.1 Synthesis of N-methylphthalimide............................................................ 45
2.3 Photoaddition reactions in solution .......................................................... 45
2.3.1 Experimental set-up .................................................................................. 45
2.3.2 Reactions of alkyl carboxylates and phenylacetates with NMP ............... 46
2.3.3 Reactions of phthalimide with phenylacetates.......................................... 54
2.3.4 Reactions of NMP with α-keto carboxylates ............................................ 57
2.4 Dehydration of photoaddition products................................................... 60
2.5 Summary..................................................................................................... 64
3 Photoaddition reactions of NMP with heteratom-containing addition
partners 66
3.1 Introduction................................................................................................ 66
3.2 Synthesis of starting materials .................................................................. 67
3.2.1 Synthesis of N-acetylated amino acids...................................................... 67
3.2.2 Reactions of phthalimides with sulfur-containing addition partners ........ 69
3.2.3 Reaction of NMP with oxygen-containing addition partner ..................... 73
3.2.4 Photodecarboxylative addition of N-protected amino acids to NMP........ 75
3.3 Summary..................................................................................................... 83
4 Synthesis of aristolactams using phthalimide derivatives as
precursors 85
4.1 Introduction................................................................................................ 85
v
4.2 Synthesis of starting materials .................................................................. 86
4.2.1 Synthesis of dimethoxy-N-methylphthalimide and its precursors ............ 86
4.2.2 Iodination of di- and trimethoxyphenylacetic acids.................................. 87
4.3 Formation of aristolactams ....................................................................... 87
4.3.1 Formation of aristolactam skeleton........................................................... 87
4.3.2 Formation of substituted aristolactams with iodo-precursors ................... 90
4.3.3 Formation of substituted aristolactams with non-iodo-precursors............ 99
4.3.3.1 Attempted electrocyclic ring closure 102
4.3.4 Further reactions for the synthesis of iodo precursors ............................ 103
4.3.4.1 Solvent study 104
4.3.5 Reactions of phthalimide and dimethoxyphthalimide with iodo-
substituted phenylacetic acids ................................................................. 105
4.3.6 Attempted iodination of precursors......................................................... 107
4.4 Summary................................................................................................... 109
5 Synthesis of phthalocyanines from photochemically derived
fluorinated phthalonitriles 111
5.1 Introduction.............................................................................................. 111
5.2 Synthesis of starting materials ................................................................ 112
5.2.1 Photochemical reactions.......................................................................... 112
5.3 Sulfonation of phthalonitrile derivatives ............................................... 115
5.3.1 Synthesis of sulfonated products............................................................. 115
5.4 Synthesis of phthalocyanines................................................................... 121
5.4.1 Synthesis of phthalocyanines from phthalonitrile precursors ................. 121
5.4.2 Synthesis of sulfonated phthalocyanines ................................................ 124
5.5 Summary................................................................................................... 127
6 Microphotochemistry performed with selected reactions 129
6.1 Introduction.............................................................................................. 129
6.2 Synthesis of starting materials ................................................................ 130
6.2.1 Synthesis of N-phthalimido carboxylic acid derivatives......................... 130
6.3 Microphotochemical reaction set-up...................................................... 132
6.3.1 Experimental set-up ................................................................................ 132
6.4 Comparison reactions .............................................................................. 135
6.4.1 Reactions of NMP with phenylacetic acid and 2-iodophenylacetic acid 135
vi
6.4.2 Reactions of NMP with selected phenylacetates .................................... 138
6.4.3 Reactions of phthalimide with selected phenylacetates .......................... 139
6.4.4 Photodecarboxylative addition of N-protected amino acids to NMP...... 140
6.4.5 Reaction of TFPN and trimethoxybenzene ............................................. 143
6.4.6 Intra-molecular cyclisation reactions...................................................... 144
6.5 Summary................................................................................................... 149
Thesis conclusions 150
7 Experimental 154
7.1 Chapter 2: Photoaddition reactions of NMP and phthalimide............ 156
7.1.1 General Procedure (A): ........................................................................... 157
7.1.2 General Procedure (A1): ......................................................................... 171
7.1.3 General Procedure (B): ........................................................................... 176
7.1.4 General Procedure (C): ........................................................................... 180
7.2 Chapter 3: Photoaddition reactions of phthalimides with heteroatom-
containing addition partners............................................................................... 186
7.2.1 General Procedure (D): ........................................................................... 186
7.3 Chapter 4: Synthesis of aristolactams using phthalimide derivatives as
precursors ............................................................................................................. 210
7.3.1 General Procedure (E)............................................................................. 214
7.4 Chapter 5: Synthesis of phthalocyanines from photochemically
derived fluorinated phthalonitriles..................................................................... 244
7.4.1 General Procedure (F):............................................................................ 244
7.4.2 General procedure (G): ........................................................................... 247
7.4.3 General procedure (H): ........................................................................... 251
7.5 Chapter 6: Microphotochemistry performed with selected reactions 256
7.5.1 General Procedure (I):............................................................................. 258
7.5.2 General Procedure (J):............................................................................. 262
7.5.3 General Procedure (J1):........................................................................... 277
7.5.4 General Procedure (K): ........................................................................... 280
7.5.5 General Procedure (J2):........................................................................... 281
8 References 289
Appendix 298
vii
For Mum and Dad
xxx
viii
Education is a wonderful thing, provided you always remember that nothing worth
knowing can ever be taught.
-Oscar Wilde
ix
Acknowledgements
Firstly I would like to thank my supervisors, Dr. Michael Oelgemöller and Dr.
Kieran Nolan. Thanks to Michael for taking me on as a PhD student and giving me
the opportunity in the first place. Thanks to Kieran for seeing my PhD through to the
end, for helping me to find solutions to any problems encountered and for staying
positive and enthusiastic, especially when I found it difficult to do the same.
To Fadi, Emma, Michael R., Sharon, Brian, Kieran J., Oksana and Alex for being a
great group to work with and an even better group to go to conferences with!
To Veronica, Damien, Vinny, John, Mary, Brendan and Catherine for all their help
over the years, and a special thanks to Ambrose and Christina for making my visits
to the hatch the highlight of many a day.
To Debbie, Yvonne and Jane for going through the whole DCU experience with me
and for helping me through the last 8 years with lots of laughs and alcohol.
To everyone in DCU who made it memorable, Alan, Áine, James, Dan, Mags and
Susan to name a few.
To the girls at home (and away!), Gillian, Deirdre, Kate and Claire for listening to
me go on and on about chemistry without telling me to shut up and for making our
nights out something I looked forward to, and still do!
To Lorraine and Gran, for all the chats, for making me laugh and most of all for
believing I could do it. Not forgetting all the prayers to St. Rita!
To Kev, for being there throughout and trying to keep me happy. An impossible job I
know.
Finally, thanks to Mum, Dad and Ashley. I couldn’t have done it without all your
love and support. Thanks for everything. We got there eventually!
x
List of abbreviations
13C-NMR carbon nuclear magnetic resonance 1H-NMR proton nuclear magnetic resonance
AIBN azobisisobutyronitrile
BET back electron transfer
C2D6CO deuterated acetone
CDCl3 deuterated chloroform
CO2 carbon dioxide
conc. concentrated
DBN 1,8-diazabicyclonon-5-ene
DBU 1,8-Diazabicyclo[5.4.0]undec-7-ene
DCM dichloromethane
dd doublet of a doublet
ddd doublet of a doublet of a doublet
DDQ 2,3-dichloro-5,6-dicyano-1,4-benzoquinone
DMAE dimethylaminoethanol
DMF dimethylformamide
DMSO-d6 deuterated dimethyl sulphoxide
equiv. equivalents
et al. and others
g gram
g/mol gram per mole
H2O distilled water
H2SO4 sulfuric acid
Harom. aromatic proton
Holef. olefinic proton
hr hour(s)
hυ light
i-butyl iso butyl group
IC internal conversion
ISC intersystem crossing
IUPAC Internal Union of Pure and Applied Chemistry
xi
J coupling constant
K2CO3 potassium carbonate
KHMDS potassium bis(trimethylsilyl)amide
m multiplet
MgSO4 magnesium sulphate
min minute(s)
ml millilitre(s)
mmol millimole(s)
mol mole(s)
MPc metallo phthalocyanine
NaCl sodium chloride
nm nanometres
NMR nuclear magnetic resonance oC degrees Celsius
Pc phthalocyanine
PDT photodynamic therapy
PET photoinduced electron transfer
Ph phenyl
ppm parts per million
s singlet
s-butyl sera butyl group
STY space-time yield
t triplet
t-butyl tertiary butyl group
TFA trifluoroacetic acid
TFPN tetrafluorophthalonitrile
THF tetrahydrofuran
TLC thin layer chromatography
UV ultraviolet
Δ heat
μg/ml microgram per millilitre
π pi
σ sigma
xii
Abstract
This research explores the application of synthetic organic photochemistry for the
preparation of new phthalimide and phthalonitrile derivatives. Photodecarboxylative
(PDC) additions of carboxylates to phthalimides were explored, this work included
addition reactions using phenyl acetates, α-keto carboxylates and protected amino
acids. Once these photo-additions were optimised using a Rayonet reactor, interest
was turned to the conversion of this chemistry to a micro-flow platform with a view
to improving the results obtained using the large-scale Rayonet reactor. It was
successfully demonstrated that the microreactor delivered comparable if not superior
results.
The possibility of using the PDC addition products as precursors for the synthesis of
aristolactams was investigated. Optimisation of a method for the preparation of
several compounds related to the aristolactam family was attempted, with the
successful preparation of two compounds achieved.
Also described is the photochemical synthesis of new phosphorescent phthalonitrile
derivatives and their respective phthalocyanines. Two of the phthalonitrile
derivatives were successfully converted to water soluble derivatives by selective
sulfonation and one such derivative was screened as a potential cell-imaging agent.
1
Chapter 1
2
1 Literature review
1.1 Photochemistry
A photochemical process may be defined as a chemical reaction that proceeds under
the influence of light. Photochemistry involves the interaction of matter with
electromagnetic radiation. Normally, any type of reaction occurs when a molecule
gains the necessary activation energy to undergo change. In the case of
photochemical reactions light provides this activation energy.
The first law of photochemistry, known as the Grotthuss-Draper law, states that light
must be absorbed by a chemical substance in order for a photochemical reaction to
take place.1 The second law of photochemistry, the Stark-Einstein law, states that for
each photon of light absorbed by a chemical system, only one molecule is activated
for a photochemical reaction. This is also known as the photoequivalence law and
was derived by Albert Einstein at the time when the quantum (photon) theory of light
was being developed.2
Energy
π*
σ
σ*π*
ππ
S0 S1 T1
Figure 1.1 An orbital energy level diagram.
An example of an orbital energy diagram is shown in Figure 1.1. In the lowest-
energy ground state molecule (S0), the lower (bonding) orbitals are fully occupied by
pairs of electrons and the upper (anti-bonding) orbitals remain unoccupied. Upon
excitation, an electron is promoted from the highest-energy bonding orbital to the
lowest energy anti-bonding orbital resulting in a (π, π*) singlet state (S1), where the
two unpaired electrons have opposite spin. In the (π, π*) triplet state (T1) the electron
spins are parallel. In molecules with heteroatoms but without extensive conjugation
3
the highest filled orbital in the ground state is often non-bonding (n), and so S1 and
T1 may be (n, π*) or (n, σ*) in nature.3
S1
S0
T1
isc
icabs.
fl.
ph.
isc
Energy
isc = intersystem crossing
abs. = absorbance
ic = internal conversion
fl. = fluorescence
ph. = phosphorescence
Figure 1.2 An example of a Jablonski diagram.
When an electron is promoted to the excited state, there are a number of ways the
energy can be released, as shown in an example of a Jablonski diagram in Figure
1.2. Photochemical reactions generally occur through S1 or T1 states since most
excited states of higher energy than these decay very rapidly to give the S1 or T1
state. Such processes are examples of radiationless decay as no light is emitted, and
are known as internal conversion if they occur without a change in spin (S2 → S1 or
T2 → T1), or intersystem crossing if there is a change in spin (S1 → T1). Decay of the
lowest excited states is much slower, because the energy gap between S1 or T1 and
the ground state (S0) is quite large. However, a chemical reaction still has to compete
with radiationless decay to the ground state, and also with luminescent decay, which
can occur in the form of either fluorescence [if there is no change of spin (S1 → S0 +
hυ)] or phosphorescence [if there is a spin change (T1 → S0 + hυ)].3
4
1.1.1 Photoinduced Electron Transfer (PET)
According to “IUPAC Glossary of terms used in Photochemistry (3rd edition)”
Photoinduced Electron Transfer (PET) is electron transfer resulting from an
electronic state produced by the resonant interaction of electromagnetic radiation
with matter. This facilitates reactions that would not usually take place in the ground
state. When molecules absorb light, and are therefore in their excited states, they may
become stronger oxidants and reductants than they would be in their natural ground
states. Upon irradiation, an electron is promoted to a vacant orbital in the excited
state where electron donation or acceptance occurs more readily in the molecule.
There are two species involved in electron transfer (ET), namely the donor (D) and
the acceptor (A). Upon electronic excitation the redox properties of either the
electron donor (D) or the acceptor (A) are enhanced (Figure 1.3).
hν+D D*(S1)ISC
D*(T1)
D*(T1) + A(So) D(So) A*(T1)+ET
Figure 1.3 Schematic representation of electron transfer.
The Rehm-Weller equation (Equation 1)[4,5] can be used to estimate the feasibility of
electron transfer using a simple free reaction energy consideration, where )D(EOx2/1
and )A(E dRe2/1 represent the oxidation and reduction potential of the donor or the
acceptor, respectively. ΔEexcit stands for the electronic excitation energy, whereas
ΔEcoul indicates the coulombic interaction energy of the products formed (most
commonly radical ions). This simplified approach allows a first approximation on the
feasibility of a PET process. Only for exergonic processes (ΔG < 0) a PET process
becomes thermodynamically favourable.
coulexcitdOx EEAEDEFG Δ+Δ−−=Δ ))()(( Re
2/12/1
Equation 1 The Rehm-Weller equation.
5
1.2 Introduction to phthalimides
Phthalimides are a group of compounds that can be described as the imides of
phthalic acids. They are aromatic compounds which contain two carbonyl groups
bound to a primary amine and their IUPAC name describes them as “isoindolin-1,3-
diones”.
N
O
O
CH3
Solid, MW: 161.16 g/mol, mp: ~137°C
NMP 1
Figure 1.4 Structure of N-methylphthalimide.
N-Methylphthalimide was the starting material for the majority of reactions that have
been carried out in this study.
1.2.1 Pharmaceutical and industrial importance of phthalimides
Thalidomide (Figure 1.5) is probably the most “famous” or “infamous” phthalimide
known today. It is a drug that was sold during the late 1950’s and early 1960’s as a
sleeping aid and also to pregnant women as an antiemetic to combat morning
sickness. It was synthesised in West Germany by the pharmaceutical company
Grünenthal in 1953 and was available in around fifty countries, (although not in the
United States), under at least forty names. It was later (1960–61) found to be
teratogenic in fetal development. Around 15,000 fetuses were damaged by
thalidomide, of whom about 12,000 in 46 countries were born with birth defects,
with only 8,000 of them surviving past the first year of life. Most of these survivors
are still alive, nearly all with disabilities caused by the drug.
Thalidomide is sold as a racemate: it was proposed that one enantiomer is effective
against morning sickness, and the other is teratogenic. However, it was later found
that the enantiomers are interconverted in vivo. Thalidomide was banned for its
6
initial intended use as sedative, however, it has been found to be effective for other
applications in the treatment of leprosy and multiple myeloma.6
Thalidomide
N
O
O
NHO
O*
Figure 1.5 Structure of Thalidomide.
Certain phthalimides are used in the agrochemical industry (Figure 1.6). As they
display a wide range of properties they can be used as herbicides, insecticides and
fungicides. An example of each is shown below, e.g. Diamate, Imidan, and Folpet.
Folpet and its derivative Captan are both non-systemic phthalimide fungicides. They
are used in water as a spray for the control of fungal diseases on turf, on fruit such as
apples, grapes and strawberries, on ornamental plants such as roses and on
vegetables when they are seeds.7 They are mainly used to improve the finish of fruit
by giving it a healthy, bright and coloured appearance. Imidan is also a non-systemic
organophosphate insecticide. It is an excellent material for the control of major pests.
The main advantage of this pesticide is its lower order of toxicity to humans and
animals.8
N
O
O
ClP(OMe)2S
N
O
O
S
SCCl3
N
O
O
Diamate(Herbicide)
Imidan(Insecticide)
Folpet(Fungicide)
Figure 1.6 Examples of phthalimides used in the agrochemical industry.
7
1.2.2 Phthalimides in organic synthesis
Phthalimides have a number of uses for example; they are used as nitrogen protecting
groups for amino acids as seen in Scheme 1.1.
+O
O
O
H2N
ROH
O
N
O
OR
OHO
150oC
DMF
Scheme 1.1 Phthalimide as a protecting group for an amino acid.
They are also used in the Gabriel synthesis (Scheme 1.2) for the preparation of
primary amines using potassium phthalimide.9
+NK
O
O
R Cl- KCl
N
O
O
R N2H4R NH2
Scheme 1.2 Gabriel synthesis.
Due to the acidity of “free” phthalimides (pKa = 9) potassium hydroxide can be used
to easily convert them to the corresponding potassium phthalimide salt. The acidic
hydrogen is removed from the phthalimide upon addition of base. This results in the
formation of a phthalimide anion which is a good nucleophile that can react with
alkyl halides to produce an intermediate N-alkylphthalimide. The N-alkylphthalimide
can then be hydrolysed to the corresponding primary amine but this can be a slow
and difficult procedure. Alternatively, N-alkylphthalimides can be treated with
hydrazine (N2H4) to give the corresponding primary amine.10 Only primary amines
can be synthesised by this method and as a result the use of the Gabriel Synthesis is
limited to methyl and primary alkyl halides.11
8
1.2.3 Photophysical and electrochemical properties of phthalimides
Phthalimides are versatile chromophores in photochemistry e.g. N-
Methylphthalimide (NMP). Although the photochemistry of phthalimide derivatives
is similar to that of carbonyl compounds, they boast additional reactivity features due
to the remarkably high oxidizing power of the excited singlet and triplet states.
The photophysical12-1
14 and electrochemical15-1
17 properties of phthalimides have been
well documented. In acetonitrile, N-alkylphthalimides show relatively simple UV-
Vis absorption spectra with absorption maxima at λmax = 235 nm (π, π*) and λmax =
290 nm (n, π*), respectively.12 The absorption spectra of NMP is shown in Figure
1.7.
0
0.1
0.2
0.3
0.4
0.5
0.6
250 260 270 280 290 300 310 320Wavelength (nm)
Abs
Figure 1.7 Absorption spectrum of NMP (obtained in acetonitrile).
At room temperature, they furthermore exhibit weak fluorescence in ethanol or
acetonitrile.13 In the absence of oxygen in alcohol N-alkylphthalimides show broad
phosphorescence centred around λmax = 450 nm. NMP is reversibly reduced to the
corresponding radical anion at ca. -1.35 V in DMF, and at ca.-1.5 V in acetonitrile
(vs. SCE).16 Based on the available photophysical and electrochemical data, it is
possible to estimate the feasibility of a photoinduced electron transfer (PET) for
various phthalimides/donor pairs (see Equation 1).
9
1.3 Photoaddition reactions involving phthalimides
1.3.1 Photoadditions of arenes
Kanaoka et al. have reported that a series of toluene derivatives add to electronically
excited N-methylphthalimide 1 to give the corresponding addition products 2 in poor
to moderate yields (5-35%).18 The best result, which was a yield of 35%, was
obtained for p-xylene (Scheme 1.3) and the abstraction of a primary hydrogen from
the benzylic position was suggested as the crucial key-step. In all cases, the
phthalimide was irradiated in the aromatic solvent and larger amounts of the starting
material 1, which had not reacted, were recovered. Furthermore, due to a competing
photoreduction reaction, the hydroxyphthalimide 3 was also isolated in low yields (1-
4%).19
N
O
O
CH3hν
+
1
N
O
CH3H3C CH3
2 (35%)
+ N
O
CH3
3 (4%)
H
CH3
HO HO
Scheme 1.3 Reaction scheme of 1 and p-xylene.
1.3.2 Photoadditions of alkenes
Five major processes20 dominate photoadditions of alkenes to phthalimides. Due to
their relevance to this work, only photoreductions will be described in detail:
1. [π2+σ2] Addition to the C(O)-N bond and formation of ring expanded
benzazepinediones
2. Electron transfer leading to photoreduction to the corresponding carbinols
3. Electron transfer to the corresponding radical ion pair which is trapped by
alcohols
10
4. Cycloaddition to the carbonyl bond and formation of oxetanes, (Paternò-
Büchi), and
5. Cycloaddition to the aromatic ring and formation of [4+2] photocycloaddition
products
The outcome of photoreactions of phthalimides with alkenes is, as a rule, determined
by the irradiation conditions and the oxidation potential of the C=C double bond in
particular, and numerous studies have been reported separately by the groups of
Mazzocchi21 and Kubo.22
The Rehm-Weller equation4,5 can estimate the viability of an electron transfer
process between the alkene and the phthalimide. In cases where an electron transfer
was endergonic with ΔGET >5 kcal/mol, [π2+σ2] addition reactions to
benzazepinediones were observed (Scheme 1.4; path A).19
N
O
O
CH3 +
[π2+σ2]
1
CH3
CH3
R = H
N
O CH3
CH3CH3
R
R
O
N
O
O
CH3
CH3 CH3
R = CH3
CH3
CH3CH3
CH3N
O
O
CH3 +
A
BPET
+ N
O
CH3
HO
CH3 CH3
CH3
N
O
CH3
HOCH3
N
O
CH3
HO
RO
CH3
CH3
+ 4
4
5 6
ROH
Photoreduction
CH3CH3
D
C
CH3CH3
Scheme 1.4 Reaction scheme of 1 and various alkenes.
11
When the electron transfer became more and more exergonic, electron transfer
started to dominate (Scheme 1.4; path B). In the presence of suitable nucleophiles,
e.g. alcohols, the intermediate formed, a radical ionic pair, was trapped in an anti-
Markovnikov fashion (Scheme 1.4; path C). In the absence of suitable trapping
agents, back electron transfer (BET, which regenerated the starting materials)
efficiently competed with proton transfer and radical combination to carbinols
(Scheme 1.4; path D). In cases where the ET was only slightly endergonic, both
pathways competed and mixtures of [π2+σ2] addition and PET products were
obtained.
1.3.2.1 Photoreductions
Mazzocchi and Klinger studied extensively the photoreaction of 1 with 2,3-dimethyl-
2-butene in acetonitrile.21b Prolonged irradiation was necessary to obtain high
conversion rates and a pair of the photoreduction products 5 and 6 were isolated in
equal yields of 13% each (Scheme 1.5). A third product was also obtained in 4%
yield, which was identified as an oxetane made from a competing Paternò-Büchi
reaction. An initial electron transfer was suggested as the key-step in the mechanism.
BET, regenerating the starting materials, competed efficiently with follow-up
reactions, as evident from the required irradiation time. Sensitization and quenching
studies with indanone and fluorene suggested that the carbinol products arise from
the singlet state of 1,21b and not from the triplet state as was previously suggested.23
CH3
CH3H3C
H3CN
O
O
CH3 +
1
+hν
PETN
O
CH3
HO
6 (13%)
H3CCH3
CH3
5 (13%)
N
O
CH3
HOCH3
CH3CH3
Scheme 1.5 Reaction scheme of 1 and 2,3-dimethyl-2-butene.
12
1.3.3 Photoadditions of oxygen containing compounds
1.3.3.1 Photoadditions of ethers
Kanaoka24 found that diethyl ether, THF and 1,4-dioxane added to 1, while Roth 25,26
and Tanabe27 independently reported on the photoadditions of ethers to phthalimide
7 and other N-substituted phthalimides. Acyclic (e.g. diethyl ether) as well as cyclic
(e.g. THF, 1,4-dioxane) ethers gave the corresponding α-addition products 10 in
modest yields of 15-39% (Scheme 1.6).
9 (<8%)
N
O
O
R1 +
10 (15-39%)
N
O
R1
HOOCH2R2
R2
R2 O R2
hν
+
3/8 (1-11%)
N
O
R1
HO H
+
NR1
O
HOR1N
O
OH
(acetone)
_
1 R1 = CH37 R1 = H
R2a = diethyl etherR2b = THFR2c = 1,4-dioxane
Scheme 1.6 General reaction scheme of 1 and 7 with various ethers.
In some cases, small amounts of the corresponding reduction, 3 and 8, and
dimerisation products 9 were isolated, and these side reactions were especially
pronounced for 7. When acetone was used as solvent, its trapping product was
additionally isolated as a minor product in a yield of 5% for the phthalimide/dioxane
pair.25 While Thalidomide solely underwent photoreduction in the presence of
THF,25 the pesticide Imidan exclusively showed fragmentation of the side-chain
when irradiated in diethylether.27
13
1.3.3.2 Photoadditions of α-trialkylsilylmethyl-substituted ethers
Intra- and intermolecular PET reactions of α-trialkylsilyl (TMS) methoxy-
substituted phthalimides were investigated by Yoon and Mariano.28 The α-TMS
group has a profound effect on the oxidation potential of the ether oxygen, which is
lowered by about 0.5 V.29 As a result of this, electron transfer from the heteroatom to
the electronically excited phthalimide becomes energetically feasible. In addition, the
presence of the silyl group furthermore enhances the efficiency and selectivity of the
subsequent photoaddition.
As an example, trimethylsilylmethyl ethyl ether yielded the related addition products
11 in satisfactory yields when irradiated in methanol (Scheme 1.7).30 However, the
photoreaction was less efficient in acetonitrile where, in an extreme case, 7 showed
no reaction at all.
N
O
O
R hν+
11 (40-48%)1 R = CH37 R = H
N
O
R
HOO
OTMS
Et MeOH
Et
Scheme 1.7 Reaction scheme of 1 and 7 with trimethylsilylmethyl ethyl ether.
1.3.4 Photoadditions of nitrogen containing compounds
1.3.4.1 Photoadditions of amines
The addition of triethylamine, N,N-dimethylcyclohexaneamine and N,N-
dimethylaniline to 1 gives the aminocarbinols 12 in low to moderate yields (Scheme
1.8)25 (each of these amines are known to be efficient photoreducing agents for
aromatic ketones31). However, the photoadditions proceeded quite slowly in general
and larger amounts of photoreduction 3 or dimerisation products 9 (R1 = CH3) were
observed.
14
hν
N
O
O
CH3 +
12 (4-37%)
1
N
O
CH3
HONR2R3
MeCN
+
3 (20-56%)
N
O
CH3
HO H
+
9 (14-44%)
N
O
HON
O
OH
NR2R3R1
R1
CH3
CH3
R1,2,3a = TEAR1,2,3b = N,N-dimethylcyclohexaneamineR1,2,3c = N,N-dimethylaniline
Scheme 1.8 General reaction scheme of 1 with various amines.
1.3.4.2 Photoadditions of α-trialkylsilylmethyl-substituted amines
Yoon and Mariano studied PET reactions of N-trimethylsilylmethyl-N,N-
diethylamine with phthalimides.30 The outcome of the photoaddition showed a
notable solvent dependency. In acetonitrile or dichloromethane, 1 gave mixtures of
the corresponding addition product 13 and the reduced hydroxyphthalimidine 3,
whereas irradiations in methanol or n-hexane only resulted in the formation of 3
(Scheme 1.9). In comparison 7 underwent reductive dimerisation to 9 (R1 = H) in
both methanol and acetonitrile.30
N
O
O
CH3hν
+
13 (41%)1
N
O
CH3
HON
NTMS
Et MeCN
Et
Et
Et
+
3 (22%)
N
O
CH3
HO H
Scheme 1.9 Reaction scheme of 1 with N-trimethylsilylmethyl-N, N-diethylamine.
15
1.3.5 Photoadditions of sulfur containing compounds
1.3.5.1 Photoadditions of thioethers
The photoaddition of some sulfides to 1 has been described by Kanaoka and
coworkers.32 In methanol, acetone and acetonitrile, a 1:2 ratio of 1 to dimethyl
sulfide gave 14 in yields of 16, 69 and 80% respectively. Using a 1:10 ratio of 1 vs.
sulfide, the yield in acetone was increased to 79%, while yields in acetonitrile were
improved to 87% when a more powerful lamp was used. A 1:2 ratio of 1 and ethyl
methyl sulfide in acetonitrile gave 14 in 52% yield, along with threo- and erythro-15
in 19% and 15% yields (Scheme 1.10) respectively. The quantum yields of the
product formation in acetonitrile were determined as Φ = 0.06 (Me2S) and 0.05
(MeSEt), respectively.
N
O
O
hν+ N
O14 (52%)
SCH2CH3
MeCN
1
HO
SCH2CH3CH3 H3C CH3 + N
O15 (34%)
SHO
CH3
CH3
CH3
Scheme 1.10 Reaction scheme of 1 with ethyl methyl sulfide.
1.3.5.2 Photoadditions of α-trialkylsilylmethyl-substituted thioethers
Yoon and Mariano described photoadditions of trimethylsilylmethyl n-propyl
thioether with 1 and 7.30 The corresponding products 16 were isolated in yields of
78-85% when irradiated in methanol (Scheme 1.11). In acetonitrile, the reaction
proceeded with much lower conversions, while larger amounts of the corresponding
dehydration products were also obtained.
16
N
O
O
R hν+
16 (78-85%)1 R = CH37 R = H
N
O
R
HOS
STMS
Pr MeOH
Pr
Scheme 1.11 Reaction scheme of 1 and 7 with trimethylsilylmethyl n-propyl
thioether.
1.3.6 Photoadditions of carboxylates
1.3.6.1 Photoadditions of alkyl carboxylates
Griesbeck and coworkers established the photodecarboxylation of ω-phthalimido
carboxylates as a versatile method for the synthesis of medium to macrocyclic ring
systems.33 Similarly, alkyl carboxylates underwent intermolecular addition reactions
to the corresponding alkyl hydroxyphthalimidines 17 in good to excellent yields
(Scheme 1.12).34 The reaction was also applied to large multigram scales using a 308
nm XeCl excimer light source.34b,35 As a result, this method represents a mild and
convenient alternative to thermal procedures.
hν
acetone/waterN
O
O
R1 CO2KR2 N
O
R1
HO R2
17 (39-89%)
+
1 R = CH37 R = H
Scheme 1.12 General reaction scheme of 1 with various alkyl carboxylates.
A highly regioselective alkylation of N-methyltrimellitic acid imide 18 has been
described.36 Photolysis in the presence of potassium propionate gave solely the para-
addition product 19 in 84% yield (Scheme 1.13). This preferred formation was
explained by exploring the differences in spin densities in the corresponding imide
radical anions. For the radical anion of 18, the spin densities were significantly
higher for the imido para-carbon atom than for the meta-carbon atom thus signifying
17
preferential para coupling. In contrast, N-methylquinolinic acid imide only showed a
slight preference for formation of its ortho isomer.
N
O
O
N
O
CH3CH3hν
acetone/water+
HO Et
19 (84%)
CO2K
18
H3CO2C H3CO2CEt
Scheme 1.13 Reaction scheme of 18 with potassium propionate.
1.3.6.2 Photoadditions of heteroatom substituted carboxylates
The incorporation of additional heteroatoms in the alkylcarboxylate affected the
respective electron donor capacity,37 and either strongly increased or decreased the
addition efficiency.38 α-Thioalkyl- and α-oxoalkyl-substituted carboxylates readily
gave the corresponding addition products 20 in modest to high yields of 51-90%
from 1. In comparison, the β-thioalkyl-substituted carboxylate remained inert,
whereas the corresponding β- to ω-oxoalkyl carboxylate reacted efficiently to give
the addition products in 45-76% yield (Scheme 1.14; Table 1.1).38 As an explanation
for the different reactivity of sulfur- vs. oxygen-substituted carboxylates, it was
concluded that oxidation of the heteroatom is dominant for thioethers. In the case of
the β-thioalkyl substrate, the sulfur atom acts as a “hole trap” due to fast non-
productive BET39 and prevents oxidation of the carboxylate. The photoreactions
involving alkylamino-substituted carboxylates gave exclusively photoreduction to 21
(R1 = H) or trapping of the solvent, acetone, leading to the formation of 22.38a
18
+ N
O
CH3
HO
22
OH
N
O
O
N
O
CH3
CH3
hν
acetone/water
+
HO
20 (45-90%)
XR1
XR1 CO2K( )n
( )n
+ N
O
CH3
R2H
3 R1 = OH21 R2 = H
1
CH3CH3
Scheme 1.14 General reaction scheme of 1 with various heteroatom substituted
carboxylates.
Table 1.1 Photoadditions of heteroatom substituted carboxylates to 1.
carboxylate yield
X n R 20 [%] 3/21 [%] 22 [%]
S 1 CH3 90 ― ―
S 1 Ph 57 ― ―
S 2 CH3 ― ― ―
O 1 CH3 57 ― ―
O 1 Ph 73 ― ―
O 1 2,4-Cl2C6H3 76 ― ―
O 2 CH3 51 ― ―
O 2 Ph 65 ― ―
O 3 Ph 55 ― ―
O 4 Ph 45 ― ―
O 9 Ph 47 ― ―
O 10 Ph 49 ― ―
O 1 H 57 <5 (3) ―
NCH3 1 CH3 ― 21 (21) ―
NCH3 2 CH3 ― 57 (21) 36
19
1.3.6.3 Intramolecular decarboxylative cyclisation reactions
N-Phthaloyl-activated α-amino acids give clean and efficient α-
photodecarboxylations (PDC) when irradiated in organic solvents.40 Remote
carboxylic acid groups could be activated for photodecarboxylation via their
corresponding carboxylates. Using the decarboxylative photocyclisation, the
synthesis of medium- and macrocyclic amines, lactones, polyethers, lactams as well
as cycloalkynes were accessible in ring sizes up to 26 (Scheme 1.15)41 and even in
multigram quantities.35a Although the oxidation potentials of carboxylates are
relatively high compared to other electron donor groups (e.g., acetate: EOx = 1.54 V
in MeCN, 2.65 V in H2O vs. SCE),42 the decarboxylative cyclisation proceeds very
efficiently and many functional groups are tolerated. As the key step in the reaction,
rapid intramolecular photoinduced electron transfer proceeds via the 3π,π* state or
the higher excited 3n,π* triplet state in the nanosecond time regime.43
23
N
O
O
YCO2K
acetone/water
hνN
Y
O
HO
Y= CH2, CO2, O2C, O, CONH, S, C C24
( )n( )m
( )m
( )n
Scheme 1.15 General reaction scheme of various intramolecular decarboxylative
cyclisation reactions.
1.4 Aristolactams
1.4.1 Naturally occurring aristolactams and their biological activity
Aristolactams44 are a small family of compounds which have a phenanthrene
chromophore (Figure 1.9) and are mainly found in the plant species
Aristolochiaceae, together with the aristolochic acids and 4,5- dioxoaporphines.45
Several aristolactams and 4,5-dioxoaporphines have been isolated from P. wightii, P.
argyrophyllum, P. schmidtii, P. acutisleginum, and P. betel.46,47 Aristolochic acids
and aristolactams are non-basic, however they are classified as aporphinoids since
20
their skeletons bear a distinct similarity to that of the aporphines. Based on their
structural relationship, it is suggested that aristolochic acids are derived from
aristolactams rather than directly from quaternary aporphine alkaloids.
NCH3
Aporphine
Figure 1.8 Structure of aporphine.
An alcoholic extract of Aristolochia indica, commonly known as “Indian birthwort”
and which is reputedly used in Indian folk medicine as an emmenagogue and as an
abortifacient, was found to show reproducible tumour inhibitory activity against the
adenocarcinoma 755-test system in mice.48 Aristolactams are also potent inhibitors
of platelet aggregation.
Taliscanine
H3CO
H3CONH
O
Aristolactam Ia
O
ONH
O
OH
Figure 1.9 Examples of aristolactams.
Many aristolactams have been discovered to be biologically active, for example
aristolactam Ia, (Figure 1.9) which has shown in vitro cytotoxicity against P-388
lymphocytic leukaemia and N S C L C N 6 (bronchial epidermoid carcinoma of
human origin), and taliscanine, (Figure 1.9) which has activity against neurological
disorders, especially Parkinson’s disease.44
More recently, aristolactams have been reported to have been isolated from the stem
of Fissistigma oldhamii,49 a herb which was used in a traditional Chinese herbal
21
formula for the purpose of treatment of rheumatoid arthritis. It has been shown that T
and B cells50-5
52 play a vital role in the function of this autoimmune disease53 and
several aristolactams were shown to have immunosuppressive abilities, by exhibiting
strong activities in the inhibition of T and B cell proliferation. The plant Aristolochia
manshuriensis has also been found to contain aristolactam derivatives of which
aristolactam A IIIa, (Figure 1.10) was found to be a potent inhibitor of the CDK2
enzyme with an IC50 value of 140nM.54 In the cell cycle CDK2 was found to have a
rate-limiting role, which led it to be considered as a potential target for antitumour
drug design.55
Aristolactam A IIIa
HO
H3CONH
O
HO
Figure 1.10 Structure of aristolactam A IIIa.
1.4.1.1 Examples of related derivatives
Alkyl- or arylmethylidene isoindolinones are known to possess a broad range of
bioactivities. The compound AKS 186, (Figure 1.11) for example, has been reported
to inhibit vasoconstriction induced by the thromboxane A2 analogue (U-46619)56
and the 4-acetoxyphenylmethylidene derivative (Figure 1.11) has been claimed to
exhibit local anaesthetic activity superior to that of procaine.57
22
AKS 186
N
O
OH
4-acetoxyphenylmethylidene derivative
N
O
N
AcO
Figure 1.11 Examples of aristolactam derivatives.
1.4.1.2 Isolation of natural aristolactams
At present, classical separation methods such as low-pressure column
chromatography and thin layer chromatography (TLC) are used in the purification of
aristolactams and their related aristolochic acids.58,59 While these methods produce
results, there are disadvantages such as poor separation with selective separation
being difficult to achieve. Recently, an efficient method for the preparative isolation
and purification of aristolactams and aristolochic acids from Aristolochia plants has
been reported.60 An oligo (ethylene glycol) separation column possessing a
“clustering function” was used to produce fractions containing similar structures
which were then further separated by preparative HPLC. This advancement enabled
target compounds with similar structures to be separated and purified selectively.
Even though developments are being made in the direct isolation of natural
aristolactams, studies are ongoing on the synthesis of these compounds and with
good reason. The examples shown previously illustrate that the aristolactam family
possesses a wide variety of biological activity. There is continuing interest in
developing further compounds in this class, as they may be useful as pharmaceuticals
such as immunostimulants and anticancer agents among many more.
23
1.4.2 Synthesis of aristolactams
Little is known about the biosynthesis of aristolactams, however, it is assumed they
are derived from aporphine alkaloids as they are biogenetically related. Aristolactams
can be synthesised thermally by the general synthetic methodology used by Couture
et al.61 Although this method is successful, there are a number of complicated steps
needed to achieve the desired compounds as shown in (Scheme 1.16) below.
N
PO
Br
H3COO
CH3 N
PO
CH3
OH3CO
BrH3CO
BnOOCH3
CHO
N
O
CH3
H3CO
Br
H3CO
BnO OCH3
N
O
CH3
H3CO
H3CO
BnOOCH3
i) KHMDS, THF -78oC to R.T
ii) aq. NH4Cl (10%)
iii) KHMDS, THF -78oC to rt
iv) Bu3SnH, AIBN benzene, reflux
29
25 26
28
27
Scheme 1.16 An example of thermal synthesis of aristolactams by Couture et al.
Following the synthesis of halogeno-N-(diphenylphosphinoylmethyl) benzamide
derivatives 25, either by the reaction of differently substituted 2-halogenobenzoic
acid or benzaldehyde and phosphorylated amine in the presence of DCC and
dimethylaminopyridine,62 they were then exposed to potassium
bis(trimethylsilyl)amide and subsequently treated with acid to give the
phosphorylated lactams 26. A Horner reaction with the appropriate
24
bromobenzaldehyde 27 gave the arylmethyleneisoindolinones 28 which, when
reacted with tributyltin hydride and AIBN resulted in the corresponding
aristolactams 29.
Another method, employed by Y. L. Choi et al63, showed the preparation of
isoindolin-1-ones 31 by reacting 2-bromomethylbenzoates 30 with various aliphatic
and aromatic amines. These were then used in a one pot synthesis of aristolactam
analogues 33 (the example shown is the formation of piperolactam A) with a number
of 2-formylphenylboronic acids 32. Interestingly, this second step took only 10
minutes to complete by performing the reaction in a microwave reactor. The reaction
proceeds via Suzuki-Miyaura coupling/aldol condensation cascade sequence. This
method is impressive but when the synthesis of 30 is taken into account, the result is
an overall seven-step procedure.64
OCH3
HO
H3COO
NH
OH3CO
HO
B(OH)2
NH
OH3CO
HO
i) ammonia, THF, rt
ii) Pd(PPh3)4, Cs2CO3, toluene/EtOH (2:1 v/v),microwave 150oC, 10 min
33
30 31Br
Br
Br
H
O
32
Scheme 1.17 Thermal synthesis of piperolactam A (33) by Choi et al.
Griesbeck and coworkers used the photodecarboxylative benzylation of phthalimides
(achieved by the same method as described previously in Section 1.3.6; Scheme
25
1.12) as a concise route to open Aristolactam analogues.65 However, the necessary
final electrocyclisation step appears problematic.66
1.5 Phthalonitriles and phthalocyanines
1.5.1 General structure and properties
Phthalocyanines (Pcs) are one of the most studied classes of functional organic
materials. It is a planar, aromatic macrocycle comprised of four iminoisoindole units
that can play host to ions derived from over 70 elements. The coordination chemistry
of the Pc ligand, which usually possesses a formal charge of 2-, is a rich and
extensive subject. Without the intervention of a metal ion, only the simple
tetraiminoisoindoline ligand exists. The general structure of a metal-free
phthalocyanine 34 and a metallo phthalocyanine (MPc) 35 are shown in (Figure
1.12).
N N
N
NNN
N
N
35
M
N N
HN
NNN
N
NH
34
Figure 1.12 General structure of metal-free phthalocyanine 34 and metallo
phthalocyanine 35.
The diverse and useful functionality of the Pc macrocycle originates from its 18-π-
electron aromatic system, which is closely related to that of the naturally occurring
porphyrin ring. The additional π-orbital conjugation afforded by the four benzo-
26
moieties, and the orbital disruption caused by the nitrogen atoms at the four meso-
positions, have a profound effect on the molecular orbital structure of the porphyrin
chromophore. The result is a bathochromic shift of the lowest-energy absorption
band (the Q-band) in the visible region of the spectrum, and a strong enhancement of
its intensity (typically λ = 680 nm, ε = ~ 2 × 105 cm2 mol-1). 67
1.5.2 Photodynamic therapy and phthalocyanines
Pcs are perhaps most well known for their commercial use as dyes and pigments due
to their bright blue or green colours. Owing to their renowned chemical and thermal
stability, they have also been investigated in a number of other fields including
information storage (CD’s), catalysis,68 chemical sensors, non-linear optical
materials69, ink-jet printing and electrophotography. They are also important
sensitisers in the application of Photodynamic Therapy (PDT)70 owing to their good
singlet oxygen generation ability.
PDT requires three basic elements: a photosensitiser, oxygen and visible light. While
separately, these elements have no effect on cancer cells, when combined they
generate singlet oxygen which destroys the targeted cancer cells. This technique
involves the topical or systemic administration of a photosensitising agent, which is
preferentially accumulated or retained by the tumour tissue, followed by illumination
of the neoplastic area with light wavelengths specifically absorbed by the
photosensitiser. The reasons for some photosensitisers localising selectively in
tumours is thought to be due to the differences in physiology of normal tissue and
tumours such as the larger interstitial volume of tumours, their poor lymphatic
drainage and the fact that tumour tissue contains many receptors for lipoproteins.71
The first generation of photosensitisers were mainly haematoporphyrin derivatives.
For example, Photofrin II,72 used in the treatment of specific tumours at a clinical
level, is a complex mixture of porphyrins originated from the chemical modification
of haematoporphyrin. It exhibits important limitations, including the low molar
extinction coefficient in the clinically useful red spectral region, which limits the
efficiency of its activation by light. The compound can also be retained by cutaneous
tissue for extended periods of time meaning patients would have to avoid bright
27
sunlight as this causes a marked skin photosensitivity. Additionally, the red
absorption maximum of Photofrin corresponds to a wavelength of 630 nm which has
reduced penetration power within most human tissues. For these reasons it is often
necessary to have repeated PDT treatments.73
It was therefore apparent that second generation photosensitisers were needed and
Pcs have been found to be excellent candidates for PDT. Their absorption
wavelength of 680 nm has the advantage of having a high penetration power into
human tissue74 while still being energetic enough to produce singlet oxygen, and is
not absorbed by the endogenous constituents of cells, thereby minimising the risk of
general photodamaging effects. Also Pcs or MPcs possess higher extinction
coefficients than porphyrins, selectively accumulate in tumour cells and can be
prepared in their pure state, which are all desirable characteristics for
photosensitisers used in PDT applications. It has been reported that fluorinated MPcs
have been shown to have several advantages over non-fluorinated derivatives as
photosensitisers for PDT.75 Zinc tetracarboxyoctafluorophthalocyanine (ZnC4F8Pc)
was shown to have a remarkable photodynamic effect, due to the fact that the Pc was
mainly accumulated in the hydrophobic lipid membrane in its photoactive monomer
form. As fluorinated Pcs are hydrophobic compounds they may favour the
hydrophobic environment.
1.5.3 Synthesis of phthalocyanines
Pcs can be synthesised from a number of benzene derivatives including phthalimides,
phthalonitriles, phthalic anhydride and 1,3-diiminoisoindoline. Phthalonitrile 36 and
1,3-diiminoisoindoline 37 are two starting materials frequently used to prepare metal
free Pcs. The most common method involves the condensation of 36 to dilithium Pc
(PcLi2) 40 by refluxing 36 and lithium metal in pentanol. When 40 is treated with
dilute acid this results in the formation of 34. Another route for the synthesis of 37, is
by reacting 36 with ammonia and sodium metal in methanol under mild conditions
(Scheme 1.18).76
28
N N
HN
NNN
N
NH
34
N N
LiN
NNN
N
NLi
40
NH
NH
NH
O
O
O
NH
O
O
CN
CN36
37
39
38
v)
i)
i)
ii)
ii)
iii)
iv)
iv)
Scheme 1.18 i) Lithium, reflux, pentanol. ii) Heat in a high boiling point solvent
with urea. iii) Treat with acid. iv) Heat; 1,8-diazabicyclonon-5-ene
(DBN) or dimethylaminoethanol (DMAE), pentanol. v) Sodium,
ammonium, methanol.
Most MPcs can be synthesised using the same methods and starting materials, with
the sole variation of including the desired M+2 salt during the condensation reactions.
29
1.5.4 Solubility of phthalocyanines
The fundamental structure of Pcs makes them, when unsubstituted, insoluble in
nearly all solvents. Due to their extended planar hydrophobic aromatic surface, Pc
molecules can interact with each other by π – π stacking interactions. The π – π
stacking interactions of Pcs affect aggregation and solubility tendencies both in
solution and in the solid state. Specifically, the aggregation behaviour of Pcs can
cause a drastic decay of the photodynamic activity and nonlinear optical properties
through reducing the active absorbing excited-state lifetime which limits their
applications in many fields77.
Water-solubility is necessary, not only to determine their physical and chemical
properties, but is also a desirable quality for various applications of Pcs, including
biological and medical applications such as PDT. Catalysis of reactions in aqueous
media, mainly the degradation of pollutants, is currently experiencing a surge in
interest,78 and this is another area where water-soluble Pcs are required.
The properties of Pcs are not only decided by the nature of their substituents on the
ligand but are also affected by the metal ion located at the core of the ligand. The
solubility can be improved significantly by introducing electron –withdrawing (-F, -
Cl, -Br, -NO2, etc.) and electron-donating (-NH2, -Ar-S-, RO-, etc.) bulky or long
chain groups.79
It has been reported that when bulky phenoxy substituents are located on the
peripheral position of the Pc core, this prohibits close self-association of the
macrocycle and can result in the formation of cubic crystals containing substantial
solvent-filled voids.80 An example of this is shown in (Scheme 1.19).
30
N N
N
NNN
N
N
44a-d
M
FF
FF
CN
CN
OHH3C CH3
ORRO
ROOR
CN
CN
RO
RO OR
OR
OROR
ORRO
ORRO
ROOR
RO
RO OR
OR
+
43
42
41
a: M = 2H, b: M = Znc: M = Co, d: M = Ni
i) ii)
Scheme 1.19 i) anhydrous K2CO3, DMF, 120oC, 72 hr; ii) microwave irradiation,
350 W, hydroquinone, appropriate metal salt, hexanol/DBU, 160oC,
10 min.
The aromatic nucleophilic substitution reaction between the anion of 2,6-
dimethylphenol 42 and tetrafluorophthalonitrile 41 resulted in the formation of
2,3,4,5-tetrakis(2,6-dimethylphenoxy)phthalonitrile 43. The most common
condensation procedure mentioned previously (lithium/pentanol) was attempted,
however this gave poor results. Microwave-assisted synthesis was then applied,
which gave the desired Pcs in high yields and purities. The metal-free Pc 44a and
three MPcs 44b-d (M = Zn, Co and Ni) were synthesised using this method.
1.5.5 Sulfonated phthalocyanines
Anionic substituents such as sulfonate, carboxylate and phosphorus-based functions
are commonly used to bestow Pcs with water-solubility, however, most of the
reported anionic Pcs contain sulfonate or sulphonic acid groups.81 These functional
groups are either attached directly to the macrocycle or linked by various spacers.
The synthesis of these compounds can be achieved by using sulfonated precursors or
31
by introducing the sulfonate function after the Pc has been formed. An example of
the former method is shown in (Scheme 1.20) below.
SO3Na
45
N N
N
NNN
N
N
46
M
NaO3S
SO3Na
SO3Na
NaO3S
HO2C
HO2C
urea, ammonium molybdate, NH4Cl, metal salt
Scheme 1.20 Synthesis of sulfonated Pcs from sulfonated Pc precursors.
The desired sulfonated Pc 46 is achieved by adding the monosodium salt of 4-sulpho
phthalic acid 45 to a mixture of the appropriate metal salt, urea, ammonium
molybdate, NH4Cl and heating in nitrobenzene at 180oC. Microwave-assisted
synthesis of 46, using the same precursors, with various metals at the core of the Pc
has also been accomplished.82
Other sulfonated Pc precursors have been reported such as substituted phthalonitriles
in which the sulphonic acid function is introduced with additional aromatic rings 47-
49 as shown in (Figure 1.13) below.
32
OHO3S CN
CN
ONaO3S CN
CN
O CN
CN
NaO3S
47 48
49
Figure 1.13 Examples of sulfonated Pc precursors.
They are prepared by the condensation of 4-nitrophthalonitrile with 4-
hydroxybenzene sulphonic acid, monosulfonated naphthol sodium salt and its
isomer: 5-hydroxy-1-naphthalene sulphonic acid respectively.81 These precursors
have been condensed by a variety of methods with a range of metal salts to give the
corresponding sulfonated MPcs.
Protected sulphophthalonitriles, an example of which is shown in (Scheme 1.21) can
also be used in the formation of sulfonated Pcs. While these precursors involve a
more complex synthesis they have proved to be quite versatile.83 They are prepared
by the chlorosulfonation of 1,2-dibromobenzene 50 and subsequent reaction with
pyrrole, the sulfonate being protected by a heterocyclic amide function before
undergoing the Rosenmund-von Braun dinitrilation to form 53. After formation of
the Pc, the protecting groups were removed by lithium 2-N, N’-
dimethylaminoethoxide in DMAE, yielding 54.
33
N N
HN
NNN
N
NH
54
HO3S
SO3H
SO3H
HO3S
i) cyclotetramerisation,ii) lithium 2-N,N-dimethylaminoethoxide, DMAE
Br
Br
Br
BrClO2S
Br
BrNO2S
CN
CNNO2S
NH
50
51 52
53
CuCNClSO3H
Scheme 1.21 Synthesis of sulfonated Pc from protected sulphophthalonitrile.
The traditional industrial approach to sulfonated Pcs is electrophilic sulfonation.
Metal-free or metallated unsubstituted Pcs are sulfonated when treated with
concentrated sulfuric acid at 80-100oC. A mixture of mono-, di-, tri- and
tetrasulfonated Pcs is usually obtained, with the degree of sulfonation determined by
high performance liquid chromatography (HPLC). Attempts to control the
sulfonation process have been made84 but after laborious experiments adjusting the
reaction conditions it was concluded that a process to target the formation of specific
sulfonated products could not be found. An example of a selective sulfonation can be
seen in (Scheme 1.22).
34
chlorosulphonic acid
N N
N
NNN
N
NN
N
N N
N
N
NN
55a-d
M
N N
N
NNN
N
NN
N
N N
N
N
NN
56a-d
M
HO3S SO3H
SO3H
SO3H
SO3HHO3S
HO3S
HO3S
a: M = Fe, b: M = Coc: M = Cu, d: M = Ni
Scheme 1.22 Example of selective sulfonation.
Metallated octaphenyltetrapyrazinoporphyrazines 55a-d (M = Fe, Co, Cu and Ni)
underwent selective sulfonation at the para position of each of the eight phenyl
groups resulting in the formation of the water soluble derivatives 56a-d.85
35
1.6 Microphotochemistry
It is becoming apparent that the time-honoured methods for practicing organic
chemistry are not sustainable and must be changed. While traditional synthesis has
been extremely successful, it is by nature wasteful, and as raw materials become
more limited, it is essential that we endeavour to make synthetic organic chemistry
more efficient.86 Despite the fact that light is regarded as a clean reagent,87 the
photochemical production of chemicals on an industrial scale remains rare, and
allthough organic chemists have not yet fully embraced microphotochemistry, i.e.
photochemistry in microstructured reactors, there has been increased interest shown
in this area as it is proving to have many advantages over conventional methods.
Some of these advantages include shorter irradiation time, fewer side-reactions,
lower quantities of reactants and solvents required which all demonstrate a more
desirable, “greener” process.
1.6.1 Examples of microstructured reactors
The term ‘(Molecular) microreactor’ refers to a confined space in which a chemical
reaction can occur and has been used in reference to micelles, zeolites,
supramolecular systems and nanoparticles.88-8 9 9 9 9
94 However, it also refers to
microstructured reactors, otherwise known as microchannelled reactors.
Microstructured reactors have demonstrated significant promise in the area of
synthetic organic chemistry, including photochemical transformations.95-9 9 9 9 1 1 1 1 1 1
106 In
general, microstructured reactors consist of a solid support with channels of only
several micrometres in width and depth (10-1000 μm). The narrow channel
dimensions promote millisecond mixing times, while their small size also prevents
“hot spots” which usually occur in batch reactors, offering better selectivity and
yields for many organic reactions. These features of rapid mixing and heat transfer
allow the use of highly concentrated reagent solutions, meaning reactions can be run
with minimal waste.
Microreactors also facilitate both process optimisation and library generation to be
done rapidly on a small scale, further reducing waste. More significant, however, is
36
the fact that microreactors effectively eliminate scale-up, opting instead for
“numbering up” with many reactors to increase output. Safety is increased and
production enhanced by avoiding larger reactors.107 As photochemistry is limited in
the development of drug candidates due to the problems associated with scale-up, in
particular with the scale-up of the light source, microreactors offer a solution to this
as large volumes of materials can be synthesised using commercially available light
sources.
Many research groups custom build microreactors for their own use. This enables
them to choose the solid substrate and glass used, as well as optimisation of path
length and depth to suit their particular needs. An example of a microchip reactor in
combination with a UV-LED-array is shown in Figure 1.14.
Figure 1.14 Quartz microchip design with 365 nm/500 mV UV-LED-array.108
Engineering of microreactors is, in itself, a significant research area, with many
groups using photochemical processes as model reactions to optimise reactor design.
The engineering of a microstructured reactor may be done using a variety of
techniques.109 The solid support used may be glass, silicon, metal, ceramic or
polymeric in nature. The choice of solid may depend on the reaction to be carried
out, for example, some polymers are not stable in all solvents. For photochemical
reactions use of glass as the solid substrate is ideal, as a transparent ‘window’
through which the reaction mixture can be irradiated is required. The channels are
created using photolithography, hot embossing, microlamination and other
microfabrication techniques.
Commercial microstructured reactors are also available and have been commonly
adopted for photochemical applications, particularly serpentine channel and the
37
falling film type reactor (FFMR). In the case of the FFMR, which utilises a multitude
of microstructured channels, the reagent solution is pumped into the microreactor
where the liquid spills over the top creating a thin film as it moves by the force of
gravity down the parallel microstructured channels. This microreactor is specifically
designed for gas-liquid reactions, e.g. oxidations and hydrogenations, where the gas
flows against the film of liquid. The high specific interface area (up to 20.000 m2/m3)
enables sufficient saturation of the film with reactant gas. This reactor type is thus
more efficient than closed channel devices, which require pre-saturation of the
reactant solution with reagent gas. Scale-up can be achieved using cylindrical reactor
models.
Figure 1.15 Cylindrical Falling Film Micro Reactor (Cyl-FFMR) for 10-fold
scale-up and the Standard version FFMR.
One of the main qualities of the serpentine reactor is its long path length, which may
range from several centimetres up to a metre or more. The dwell-reactor produced by
Mikroglas (Figure 1.16), for example, has a total path length of 1.15 m (20 turns) on
a 118 mm x 73 mm aperture. This reactor consisted of a (bottom) serpentine channel
with a second (top), heat-exchanging channel through which water is passed in order
to control the reactor temperature. The longer path length can be used to increase
residence time, and is therefore suited to reactions which require longer periods of
irradiation. In the serpentine reactor the reagents may be either pre-mixed, as in the
case of the dwell-device, or mixed “on-chip” in cases with two separate inlets leading
into a single channel in either a “T” or “Y” shape.
38
Figure 1.16 Dwell Device (Mikroglas).
The photochemical reactions carried out in microstructured reactors can be split into
three categories. Firstly, homogeneous reactions (such as photocyanation,110 [2+2]-
cycloadditions,111,112 the Barton reaction,113 photochemical pinacolisation114),
secondly, heterogeneous reactions between liquid and gaseous reagents, as carried
out in the FFMR, (e.g. [4+2]-cycloadditions of singlet oxygen115,116) and lastly as
catalytic processes using semiconductors (such as catalytic reactions using titanium
dioxide117-1
119). A review of these categories of organic photochemistry has been
published120 and isolated examples of homogenous reactions will be presented here.
1.6.2 Selected examples of micro-photochemical reactions
In these reactions the reagents are all in the same phase, i.e. all in solution. Therefore
there are few additional requirements for the microstructured reactor beyond the
ability to pump the reagents in solution through the reactor. One of the earliest
reported photochemical reactions in a microstructured reactor was the photo-
pinacolisation of benzophenone 57 in isopropanol (Scheme 1.23).114 The
microstructured reactor was fabricated in-house by bonding a patterned silicon wafer
to a quartz wafer, the advantage of this technique being that the quartz substrate
allows reaction and detection using UV light of lower wavelengths than permitted by
glass substrates such as Pyrex.121 The light source used was a mini UV lamp, which
provided light of 365 nm. The typical concentration of the benzophenone solution
was 0.5 M. The use of a concentrated solution effectively demonstrated the
advantage of a microstructured reactor, as the shallow channel depth ensured
complete irradiation of the reaction mixture which would not have been possible
39
under conventional photochemical set ups. The progress of the transformation was
monitored off-chip using HPLC and on-line using UV-spectroscopy.
57 58 (60%)
O
Ph
OHHO
PhPhPh
hν OOH+ +
Scheme 1.23 Reaction scheme of the photo-pinacolisation of 57.
The authors reported that this reaction required flow rates of less than 10 μl min-1 to
ensure adequate residence time on the chip. The reaction is known to follow a radical
reaction pathway and it is reported that the longer the residence time of the reaction,
the greater the conversion to benzopinacol 58. This is because the longer residence
time results in the increased absorbance of light and provides sufficient time for the
excited species to diffuse and react with 57, although flow rates above 3 μl min-1
were used to avoid precipitation of product 58 in the microstructured reactor. Above
this threshold, crystallisation of the product was observed in the effluent storage
device instead. At a flow rate of 4 μl min-1 conversions of up to 60% were achieved.
Fukuyama et al. carried out an investigation into the use of microstructured reactor
technology for photochemical [2+2]-cycloadditions (Scheme 1.24).112 This study
demonstrates the application of the previously mentioned dwell device (Figure 1.16)
for a range of substrates using a common high pressure mercury lamp (300 W) as the
light source. The model reaction examined was the reaction of cyclohex-2-enone 5
with vinyl acetate 60.
O
OAc
OAc
O
+
59 60 61 (88%)
hν
Scheme 1.24 Reaction scheme of a photochemical [2+2]-cycloaddition.
At a flow rate of 0.5 ml/hr, which corresponds to a residence time of 2 hours, 61 was
obtained in a yield of 88%. This was compared to a batch reactor (10 ml) irradiated
40
using the same light source for 2 hours, which yielded only 8% of 61. This
demonstrates clearly that the use of microstructured reactor technology can both
shorten irradiation times and increase yield. The reaction was repeated with two
reactors in series at a flow rate of 1 ml/hr, which resulted in a similar yield of 85%.
The use of microstructured reactors can decrease or even eliminate unwanted side
reactions as rapid flow rates decrease the residence time of the substrates and can
ensure that the products are rapidly removed from the reactor. Sakeda et al. have
demonstrated this theory using the asymmetric photosensitised addition of methanol
to (R)-(+)-(Z)-limonene 62 as a model reaction (Scheme 1.25).122
H3CO OCH3
+ +CH3OH
hν, sens.
62 656463
Scheme 1.25 Reaction scheme of 62 and methanol.
Three microstructured reactors of different dimensions were made from quartz and a
low-pressure mercury lamp (40 W) was used as the light source. A study of the effect
of channel size on photon efficiency was carried out. With decreasing channel size,
photon efficiency was shown to increase and was significantly greater for
microstructured reactors than batch conditions. The reason for this was attributed to
high spatial illumination homogeneity, excellent light penetration and short exposure
times. In addition, the diastereomeric excess (d.e.) of the photoproduct was found to
be slightly larger than that obtained under batch conditions. This was explained by
suppression of side reactions in the microstructured reactors as, due to the short
space of time the reactants and products spend under irradiation, there is less chance
of either a secondary product being formed or of the product being converted to
another compound.
41
Thesis proposal
Microchemistry is an emerging area of interest, as described in the literature review
(Chapter 1). Microreactors are known to use less solvent, be more energy-efficient
and result in less side-reactions making them attractive as a prospective method for
organic synthesis. With this in mind, we decided to investigate the potential of
performing various photochemical reactions in a microreactor.
Investigating the feasibility of microreactors in organic photochemistry:
To do this, we will first need to acquire results from a “conventional” method and
then perform the same reactions in a microreactor and finally compare both sets of
results for any similarities or improvements.
Phthalimide chemistry:
As phthalimide chemistry was a focus for our group, particularly
photodecarboxylative (PDC) additions of carboxylates to phthalimides, several of
these reactions will be used as model reactions, to both optimise the microreactor set-
up and use as comparison reactions.
Aristolactam synthesis:
Aristolactams are an important family of compounds possessing a wide variety of
biological activity. Continuing on from the phthalimide chemistry, it will be
investigated whether aristolactams can be synthesised from the PDC addition
products via an efficient photochemical method. We wish to optimise this chemistry
first by conventional methods and then determine if it can be transferred to a
microreactor. If successfully transferred, then the value of microphotochemistry
could be demonstrated for compound libraries.
Phthalonitriles and phthalocyanines:
Another focus of our group is phthalocyanine (Pc) chemistry. Although it is possible
to synthesise Pcs from phthalimides, in this case we will explore the option of using
phthalonitriles as the precursors. The application of synthetic organic photochemistry
for the preparation of new sulfonated phthalonitrile derivatives will be investigated,
42
as water solubility is a desirable feature of Pcs for application in PDT and cell
imaging. The phthalonitrile chemistry will also be performed in a microreactor and
compared to conventional methods.
Ultimately we wished to demonstrate that microphotochemistry can be used as an
efficient tool in organic synthesis.
43
Chapter 2
44
2 Photoaddition reactions of NMP and phthalimide
2.1 Introduction
In this chapter photoaddition reactions are introduced. NMP is the starting material
of choice which will be synthesised and then reacted with a number of addition
partners such as alkyl carboxylates, phenyl acetates and α-keto carboxylates. PET
will be introduced and the mechanisms of these reactions will be discussed. A variety
of photoaddition reactions with phenyl acetates will also be performed using
phthalimide as the starting material and any differences in the results obtained
discussed.
Several photoaddition products will then be dehydrated to form the related
arylmethylenesioindolin-1-ones, which have the general structure of the open
analogues of aristolactams which were discussed in Chapter 1 and will be dealt with
in Chapter 4.
45
2.2 Synthesis of starting material
2.2.1 Synthesis of N-methylphthalimide
N-Methylphthalimide (NMP) 1 was the starting material of choice used for most of
the reactions described in this and subsequent chapters. It is available commercially,
however it is possible to synthesise it quite easily from phthalic anhydride and N-
methylformamide according to a method described by Schindlbauer123 (Scheme 2.1).
The pure product (1) was afforded in a yield of 71% and the 1H-NMR revealed the
presence of the NCH3 group at 3.11 ppm in CDCl3.
O
O
O
NH
N
O
O
CH3H3C8 h
+140-150ºC
1
O
H
Scheme 2.1 Experiment 1.
2.3 Photoaddition reactions in solution
2.3.1 Experimental set-up
For the irradiation experiments a Rayonet photochemical chamber reactor was used
(Figure 2.1 and Figure 2.2). The reactor was fitted with 16 RPR-3000 Å lamps (λ =
300±20 nm). Schlenk flasks (λ ≥ 300 nm) were used and the reaction mixture was
constantly purged with a slow stream of N2. To avoid overheating, a cold finger was
used. A short Teflon tube was inserted into the second Suba Seal to act as an outlet
for the gas to prevent pressure build up. The progress of the reaction was monitored
by TLC analysis, or by connecting a bubbler to the Schlenk flask containing a
saturated solution of barium hydroxide, used to detect the presence of carbon dioxide
which is only formed when the reaction is in progess.
46
1
2
3
4
Figure 2.1: Rayonet photoreactor. Figure 2.2: Experimental set-up.
Figure 2.2 1: Pyrex tube containing reaction mixture, 2: Cold finger to keep
reaction cool, 3: Outlet to prevent pressure build-up, 4: Inlet for N2.
2.3.2 Reactions of alkyl carboxylates and phenylacetates with NMP
In general, 1 was irradiated in the presence of 3 equivalents of a potassium
carboxylate, the latter which was generated in situ from the carboxylic acid and
K2CO3, resulting in the formation of the desired photoproducts (Scheme 2.2). In
experiment 2, i-butyric acid was used as the addition partner and, following 7 hours
of irradiation, the product 66a was obtained in a yield of 74%. In experiment 3, vinyl
acetic acid was the reagent of choice. After irradiating for 5 hours, the yield was
found to be 24% despite complete conversion of 1 being achieved (Table 2.1). The
C-OH peak for both products was found around 90 ppm in the 13C NMR spectra, in
C2D6CO and CDCl3 respectively.
N
O
O
N
O
CH3+hν
CH3 R OK
O
acetone / water
HO R
1 66a R = i-Pr66b R = allyl
Scheme 2.2: Experiments 2 and 3.
47
Table 2.1: Photoadditions involving 1.
compound R time [hr] yield [%] 13C-NMR
[ppm] C-OH
66a i-Pr 7 74 93.2a
66b allyl 5 24 90b
a in acetone-d6, b in CDCl3
In the 1H-NMR spectrum of 66b (Figure 2.3), the N-methyl group and one of the
peaks corresponding to the CH2 group overlap at around 2.75 ppm. The peak
representing the OH group is found at 4.0 ppm as a sharp singlet, and in the olefinic
region, peaks were observed between 4.8 and 5.3 ppm. In the aromatic region the
characteristic peaks representing the four aromatic protons were found.
2.53.03.54.04.55.05.56.06.57.07.5 ppm
2.
69
52
.7
15
2.
73
12
.7
41
2.
75
02
.8
61
2.
86
52
.8
68
2.
87
72
.8
80
2.
88
32
.8
98
2.
90
12
.9
04
2.
91
32
.9
16
4.
00
84
.8
74
4.
87
64
.8
78
4.
90
14
.9
03
4.
93
64
.9
40
4.
97
94
.9
82
5.
09
15
.1
07
5.
11
15
.1
16
5.
12
75
.1
32
5.
13
45
.1
36
5.
15
05
.1
52
5.
16
95
.1
75
7.
35
17
.3
57
7.
36
67
.3
70
7.
37
27
.3
77
7.
38
57
.3
91
7.
47
07
.4
88
7.
51
77
.5
19
7.
53
67
.5
38
7.
54
57
.5
47
7.
55
17
.5
53
7.
56
47
.5
66
3.87
1.00
0.95
0.96
0.97
0.97
0.95
0.95
1.94
CH3
CH2
OHHarom
N
O
CH3
HO
Holef
Figure 2.3 1H-NMR spectrum of 66b in CDCl3.
Both photoadditions of alkyl carboxylates to N-methylphthalimide 1 resulted in the
formation of alkylphthalimidines as the only products. As mentioned previously, in
experiment 2, the addition of iso-butyric acid to NMP resulted in a 74% yield after 7
hours irradiation. In experiment 3 however, the addition of vinyl acetic acid to NMP
4.95.05.15.2 ppm
48
only resulted in a yield of 24% after 5 hours irradiation. It was assumed, due to the
stability of the corresponding allyl radical, that this reaction would proceed readily
even with a short irradiation time. Alternative reactions involving the C=C double
bond, for example Paternò-Büchi reactions or photoadditions via C-H activation,
might have successfully competed with the desired photodecarboxylation in this
case.124 No evidence of these proposed side-reactions was found although, as a
consequence of their carboxylic acid functionalities, the resulting products would
have been water soluble and extracted during work-up.
The proposed mechanism for the photodecarboxylative addition is illustrated in
Scheme 2.3.125,126 Triplet sensitisation by acetone is followed by single electron
transfer (SET) from the carboxylate to the triplet excited phthalimide. Although the
oxidation potentials of carboxylates are relatively high compared to other electron
donor groups (e.g. acetate: EOx. = 1.54 V in MeCN, 2.65 V in H2O vs. SCE127)
intramolecular electron transfer via the excited 3π,π* triplet state (E00 = 3.1 eV) or
the higher 3n,π* state (E00 ≈ 3.6 eV) are both energetically feasible. Subsequent
decarboxylation of the carboxy radical yields the corresponding C-radical. The rate
for CO2 loss is controlled by the stability of the corresponding alkyl radical and is
estimated to be in the range of 109-1010 s-1 for simple alkyl acyloxy radicals.128
Protonation, intersystem crossing and C-C bond formation result in the desired
photoaddition products (path A). Alternatively, BET generates the corresponding
carbanions, which are protonated by water (path B).129
N
O
O
N
O
CH3
+CH3 R O
O
HO R
B
3Sens., PET
- CO2
1. H+
2. C-C1. BET2. H+
N
O
O
CH3 R
N
O
O
CH3 HR
A
+
+
Scheme 2.3 Mechanism of photodecarboxylative addition of carboxylates to
phthalimide.
49
For vinyl acetate, an alternative mechanism involving electron transfer from the C=C
double bond can be postulated (Scheme 2.4). Subsequent α-decarboxylation leads to
the common allyl radical. A similar competitive mechanism has been described by
Kurauchi and co-workers for the decarboxylative addition to 1-methyl-2-phenyl-1-
pyrrolinium perchlorate.130 Based on fluorescence quenching experiments the
authors concluded that electron transfer proceeded from both donor sides yielding the
same final product. A similar behaviour might be operating here as well.
N
O
O
CH3
3Sens.
ETC=C
CO2
N
O
O
CH33 *
- CO2
O
O+
Scheme 2.4: Alternative mechanism of allylation.
As seen in Scheme 2.5 and summarised in Table 2.2, NMP in the presence of 1.5
equivalents of different potassium phenyl acetates in acetone-water (50:50), for 1–5
hours gave addition products 67a-i in yields of 18–78%. The characteristic C-OH
signals in the 13C-NMR spectra were found around 90 ppm for all compounds. For
67b, it was calculated from the crude NMR that only 52% of the starting material
had reacted, and therefore the % yield was calculated based on conversion as 56%.
50
N
O
O
N
O
CH3+hν
CH3CO2K
acetone / water
HO
1 67a-k
R4
R3
R3
R4R2
R2
R1 R1
Scheme 2.5: Experiments 4-14.
Table 2.2: Photoadditions of phenyl acetates to 1.
compound R1 R2 R3 R4 time [hr] yield [%] 13C-NMR
[ppm] C-OH
67a H H H H 1 54 90.7b
67b H H H CH3 2 53 90.9c
67c H H H OH 5 18 91.1c
67d H H H OCH3 4 78 91.3c
67e H H H F 2 36 91.8c
67f H H H Cl 5 29 (56)a 90.5b
67 g H H Cl Cl 3 53 90.1b
67h H Br H H 5 35 90.3c
67i Ph H H H 3.5 76 92.2c
67j H CH3 H H 3 63 90.4c
67k H CF3 H H 7 46 90.2c a yield based on conversion, b in CDCl3, c in C2D6CO.
A representative 1H-NMR spectra of photoaddition product 67a is shown in Figure
2.4. The methyl group at the N-terminus is found as a singlet at 2.88 ppm. The two
doublets at 3.09 and 3.46 ppm represent the bridging CH2 group between the original
isoindolinone and the newly introduced phenyl ring. These two hydrogens are
chemically inequivalent, which is why they appear as two doublets and not as a
single peak. The OH group was found as a broad peak at 3.7 ppm. In the aromatic
region the peaks representing the nine aromatic protons can be found between 6.8-
7.5 ppm. Four of these protons can be assigned to the aromatic ring of the original
isoindolinone and five to the newly introduced phenyl ring.
51
3.03.54.04.55.05.56.06.57.07.5 ppm
2.
87
8
3.
07
53
.1
10
3.
44
43
.4
79
3.
66
4
6.
84
56
.8
50
6.
86
56
.8
69
7.
06
27
.0
66
7.
07
07
.0
74
7.
08
47
.0
93
7.
09
77
.1
02
7.
10
67
.1
16
7.
11
97
.1
31
7.
13
67
.2
44
7.
25
97
.2
63
7.
29
97
.3
01
3.00
1.05
1.00
0.95
1.99
3.04
0.50
1.46
1.03
1.00
0.99
N
O
CH3
HO
CH3
CH2OH
Harom
Figure 2.4 Representative 1H-NMR of 67a in CDCl3.
Major advantages of the photodecarboxylation protocol are its simple procedure and
the usage of carboxylic acids. These starting materials are readily accessible in large
quantities with broad structural diversity, and are additionally stable in comparison to
other thermal methods e.g. SmI2-mediated coupling of organic halides (SmI2/R-
X),131a addition of organometallic compounds (R-Mg-X or R-Li),131b-d or alkylation
with organic halides using lithium in liquid ammonia (Li/NH3/R-X),131e respectively.
The efficiency of the PDC approach becomes especially apparent when comparing
the benzylation of N-methylphthalimide with toluene or phenyl acetate (Scheme
2.6). As reported by Kanaoka and co-workers, simple hydrogen abstraction gives the
corresponding benzylated product in low yield (5%) and with poor selectivity and
conversion (30%).18 In contrast, PDC exclusively yields the benzylated product in
high yield and purity.
7.07.27.4 ppm
52
N
O
O
CH3
PhCHCO2K
C-H PDC
N
OH
O
CH3 N
O
CH3
HO Ph
N
O
CH3
HO Ph
5%2% 54%
PhCH3
hν hν
Scheme 2.6: Alternative benzylation procedures.
In the case of 67c the product is obtained in a low yield of 18%, even though
complete conversion of starting material occurs as was evident by TLC. This is
probably due to the formation of the potassium salt (phenolate) of the desired product
(Scheme 2.7) which should be water soluble and so remains in the aqueous layer
during work-up. This occurs because the pH of the reaction solution rises during
irradiation due to the formation of KOH. No attempt was made to recover this
product.
N
HOO K
CH3
O
N
O
O
+CH3
hν
- CO2N
O
CH3
+ KOH
CO2K
HO
-H2O
HO OH
67c
Scheme 2.7 Formation of potassium salt (phenolate) of 67c.
53
In the case of 67f the conversion was calculated from the 1H-NMR to be 52% after a
total of 5 hr irradiation. This may be due to a competitive reaction taking place in
which the simple PDC product is formed (Scheme 2.8).
Cl
CO2K PET
Cl
CO2
Cl
CH3
- CO2
Cl
BET
Cl
CH2- OH
+ H2O
Scheme 2.8 Formation of simple PDC product for experiment 9.
As seen in Scheme 2.3, path B results in the formation of the simple decarboxylation
products (-CO2H ↔ -H exchange). Although these simple decarboxylation products
were sometimes detected by TLC or in the crude NMR spectra, no attempt was made
to isolate these compounds. In most cases, they were removed during drying under
vacuum due to their volatility. For 67f, as the conversion was so low, simple PDC
might be more pronounced.
The reaction of 1 with potassium L-3-phenyllactate also resulted in the formation of
67a (Scheme 2.9) with a yield of 21% after 4 hours irradiation. As previously
mentioned, the yield obtained with potassium phenylacetate as the addition partner
was found to be 54% after only 1 hour of irradiation.
N
O
O
N
O
CH3+hν
CH3 acetone / water
HO
1 67a (21%)
CO2K
OH
Scheme 2.9 Experiment 15.
54
The differences in yield can be explained by the differences in mechanism of both
reactions. While both mechanisms are similar, in the case of potassium L-3-
phenyllactate an extra step is needed. Decarboxylation is followed by the loss of
formaldehyde before C-C bond formation can afford the desired photoproduct as
depicted in Scheme 2.10. This means that the reaction will take longer to complete
and hence requires a longer irradiation period.
N
O
O
CH3
1. ETN
O
O
CH33 *
- CH2O
2. - CO2
N
O
CH3
HO
67a
O2C
OH OH
Scheme 2.10 Mechanism of 1 and potassium L-3-phenyllactate.
2.3.3 Reactions of phthalimide with phenylacetates
A major shortcoming of the original PDC procedure is the need to have N-
substituents on the phthalimide due to the rising pH during irradiation (final pH ~9-
10). With “free” phthalimide the initially formed benzylated-hydroxyphthalimidines
are consequently obtained as their potassium salts and cannot be isolated easily.
Early attempts to convert these salts directly to the corresponding
arylmethyleneisoindolin-1-ones by means of an acidic work-up and subsequent
extraction, resulted in complex mixtures with unreacted starting materials. Since the
acidity of phthalimide (pKa = 8.3) differs considerably from that of common
55
carboxylic acids (pKa = 5-6), a mixture of acetone and pH 7 buffer solution was
therefore applied for the irradiation reactions.
A number of reactions were performed using phthalimide as the starting material and
acetone/pH 7 buffer (1:1) as the solvent, as shown in Scheme 2.11. In most cases the
results obtained showed greater yields with shorter irradiation times than the related
reactions using 1 as the starting material (Table 2.3).
N
O
O
N
O
R1+hν
R1 CO2Kacetone / water or pH7 buffer
HO
1 R1 = CH37 R1 = H
67b, e, j, k, R1 = CH3 68a-d, R1 = H
R3
R3R2
R2
Scheme 2.11 Reaction of 1 and 7 with various phenylacetates.
Table 2.3 Results obtained for photoproducts from both 1 and 7.
compound R1 R2 R3 time [hr] yield [%]
67b CH3 4 47
68a H H CH3
3 92
67e CH3 4 39
68b H H F
3 85
67j CH3 3 63
68c H CH3 H
3 57
67k CH3 7 46
68d H CF3 H
6 63
The only exception to this was experiment 20 which, after the same irradiation
period of 3 hours, gave 68c in a yield of 57% which was comparable to 67j (63%
yield).
56
2.53.03.54.04.55.05.56.06.57.07.5 ppm
2.
25
2
3.
35
13
.3
86
3.
40
63
.4
40
5.
34
7
7.
03
77
.0
48
7.
05
97
.0
68
7.
07
87
.0
87
7.
09
37
.1
09
7.
11
17
.1
21
7.
12
47
.2
37
7.
25
67
.4
15
7.
41
87
.4
19
7.
43
07
.4
36
7.
48
1
3.00
1.07
0.99
0.65
1.08
1.96
1.08
0.99
1.02
2.00
0.72
NH
HO
O
H3C
Harom CH2
OHNH
CH3
Figure 2.5 Representative 1H-NMR of 68c in C2D6CO.
A representative 1H-NMR of 68c is shown in Figure 2.5. Obviously the main
difference from the previous representative 1H-NMR spectra is the absence of the N-
CH3 peak ~3 ppm and the presence of the NH peak found as a broad singlet at 7.8
ppm. The doublets representing the bridging CH2 group were found at 3.3 and 3.4
ppm, while the methyl group appeared as a singlet at 2.3 ppm. In the aromatic region,
the peaks representing the 8 aromatic protons were found between 7.0 and 7.6 ppm,
four representing the newly introduced aryl ring and the remaining four representing
the aromatic ring of the original isoindolinone. The broad peak found at 5.3 ppm
corresponded to the OH group.
57
2.3.4 Reactions of NMP with α-keto carboxylates
Following the general procedure described previously, 1 was irradiated in the
presence of the sodium salts of α-keto acids. Upon irradiation, either the alkylated or
acylated photoproducts were obtained in yields of 26-69%.
R
N
O
O
CH3 +O
N CH3
O
HOhν
+ N CH3
O
HO R
O
69a-e 70a-e
R CO2Na acetone / water
1
Scheme 2.12 Experiments 22-26.
Table 2.4 Photoadditions of α-keto carboxylates to 1.
yield [%] compound R time [hr]
69 70
a i-Pr 3 29 -
b i-Bu 4.5 - 26
c t-Bu 2.5 69 -
d s-Bu 3 39 -
e CH2Ph 6.5 52 -
As we can see from Table 2.4, experiment 23 resulted in the acylation product 70b
being formed in a yield of 26%. In all other cases, the alkylation product was formed.
In experiment 25, as there are two chiral centres present, a diastereomeric mixture of
like- and unlike-69d (like = R,R / S,S and unlike = R,S) was formed in a ratio of
58:42, (d.e. = 16%), however despite column chromatography they could not be
separated.
58
NCH3OHHarom
0.51.01.52.02.53.03.54.04.55.05.56.06.57.07.5 ppm
0.
54
00
.8
35
0.
85
30
.8
72
0.
89
80
.9
44
0.
99
81
.0
16
1.
03
51
.0
56
1.
13
41
.2
24
1.
24
11
.3
38
2.
12
42
.2
62
2.
93
92
.9
43
5.
22
15
.2
42
7.
51
17
.5
13
7.
51
97
.5
29
7.
53
27
.5
35
7.
53
87
.5
47
7.
55
07
.5
53
7.
58
97
.6
05
7.
60
8
1.14
3.44
3.31
0.91
3.69
3.83
2.58
4.21
3.06
3.00
0.59
0.66
2.04
3.84
2.20
2 x CH3
Like and UnlikeLike and Unlike Like and Unlike
1H 1H 1H3H
N
O
CH3
HO
Figure 2.6 Representative 1H-NMR spectrum of 69d in C2D6CO.
The 1H-NMR spectrum of photoaddition product 69d is shown in Figure 2.6. It
could not be determined which diastereoisomer (like or unlike) was the major/minor
component. The N-terminus methyl groups were found as singlets at 2.94 ppm. Two
doublets representing the CH3(CH) groups were found at 0.53 and 1.23 ppm
respectively. Two triplets representing the CH3(CH2) groups were found at 0.85 and
1.02 ppm respectively. The CH2 and CH groups for both were found as multiplets
between 0.46 and 2.26 ppm. The OH groups were found as broad singlet peaks at
5.22 and 5.24 ppm. In the aromatic region the peaks representing the eight aromatic
protons can be found between 7.51 and 7.70 ppm.
Out of experiments 22-26 only one of them (experiment 23) yielded the acylation
product 70b. This is in line with the literature results.132 For the other reactions, the
alkylation product is obtained in moderate to good yields. The reaction cascade is
initiated by electron transfer (ET) from the α-keto carboxylate to the triplet excited
phthalimides (Scheme 2.13).
1.01.52.0 ppm
59
N
O
O
CH3
1. ET
CO2N
O
O
CH3
3 *
- CO
R
O
2. - CO2 R
O
N
O
CH3
HO R
N
O
CH3
HO RO
AlkylationAcylation
Path APath B
Scheme 2.13 Proposed mechanism for reactions of α-keto carboxylates with 1.
It has already been reported that α-keto carboxylates can be involved as electron
donors in PET processes.133 After rapid decarboxylation, the acyl radicals which
were formed from the carboxyl radicals can undergo subsequent decarbonylation.
Based on the rate of this secondary thermal process, two reaction pathways are
likely. The rate for decarbonylation is controlled by the stability of the corresponding
alkyl radical. For the most stable acyl radicals, the C-C bond formation step (Path B)
can successfully compete with the decarbonylation, whereas for the more reactive
acyl radicals decarbonylation precedes C-C bond formation (Path A). The moderate
diastereoselectivity obtained for 69d also accounts for a radical combination.
Therefore for the alkylation products 69a-e, photodecarboxylation is rapidly
followed by decarbonylation prior to the radical addition step for their corresponding
substrates.
60
2.4 Dehydration of photoaddition products
A selection of previously synthesised photoaddition products, including four aryl-N-
methylisoindolin-1-ones and one arylisoindolin-1-one, were dehydrated to the
corresponding arylmethyleneisoindolin-1-ones as shown in Scheme 2.14. They were
obtained in moderate to good yields via acid-catalysed dehydration in DCM. In
almost all cases, high E-selectivities were obtained as confirmed by 1H-NMR
spectroscopy. The results are summarised in Table 2.5.
N
O
R2
N
O
R1
HO R4
R2
R1
R4
R3
R3
DCM
conc. HCl
71a-e67a, b, g, j and 68c
Scheme 2.14 Experiments 27-31.
Table 2.5 Dehydration reactions of previously made photoproducts.
compound R1 R2 R3 R4 1H-NMR [ppm]
CHolefa (E)
yield [%] d.e. [%]
71a CH3 H H H 6.5b 68 E/Z 80
71b CH3 H H CH3 6.5b 62 E/Z 82
71c CH3 H Cl Cl 5.9b 74 E/Z 64
71d CH3 CH3 H H 6.7c 58 E 68
71e H CH3 H H 6.7c 67 Z 52 a determined from integration of Holef peaks in 1H-NMR spectra, b in CDCl3, c in C2D6CO.
The configurations of the two isomers (E/Z) were assigned by comparison with
known analogues reported by Ang and Halton.134
61
N
OZ-isomer
CH3
HCH3
N
O
CH3
H3CH
δ [CHolef.] = 5.70 >E-isomer
δ [CHolef.] = 5.38 ppm Scheme 2.15 Assignment of Z- and E-isomers according to Ang and Halton.
The olefinic hydrogen of the Z-isomer is influenced by the anisotropic effect of the
aromatic ring (indicated as blue arrow in Scheme 2.15) and is found at higher
chemical shifts than it’s E-counterpart. This general trend was applied when
assigning all subsequent isomers of compounds prepared.
In experiments 27-29, the most abundant isomer was found to be the E-isomer. The
highest d.e of 82% was obtained for 71b. Purification was carried out by column
chromatography, however this failed to separate the isomers. In experiment 30, 71d
was also found to contain a majority of the E-isomer and this was successfully
isolated by washing the product with a little acetone. The Z-isomer was removed
along with the impurities. In experiment 31, which was the sole example of a
photoproduct using phthalimide (7) as the starting material, 71e was found to contain
a majority of the Z-isomer. This was also successfully isolated by the same
purification method as in experiment 30. For comparison, the 1H-NMR spectra of
both 71d and 71e are shown below in Figure 2.7 and Figure 2.8 respectively.
62
Harom.
N
O
H3C
CH3
2.53.03.54.04.55.05.56.06.57.07.58.0 ppm
2.
35
2
2.
83
62
.8
38
2.
84
12
.8
72
3.
42
8
6.
66
87
.0
12
7.
01
47
.0
30
7.
03
27
.0
34
7.
28
77
.2
93
7.
30
57
.3
08
7.
30
97
.3
11
7.
31
97
.3
21
7.
32
37
.3
28
7.
35
57
.3
58
7.
37
37
.3
77
7.
38
67
.3
93
7.
39
4
3.00
1.06
2.51
3.04
0.97
0.97
1.04
2.70
1.29
1.00
0.94
NCH3
CH3
Holef.
Figure 2.7 1H-NMR spectrum of 71d in C2D6CO.
The N-methyl group of 71d was found as a singlet at 3.4 ppm, while the methyl peak
also appeared as a singlet at 2.4 ppm. The characteristic Holef peak was found at 6.7
ppm. The peaks representing the aromatic protons were found between 7.0 and 7.8
ppm.
7.07.5
63
NH
O
H3C
HolefNH
CH3
2.53.03.54.04.55.05.56.06.57.07.58.08.59.09.5 ppm
2.
44
6
2.
84
02
.8
41
2.
84
42
.8
75
6.
83
37
.2
22
7.
22
67
.2
40
7.
25
27
.2
58
7.
26
27
.2
70
7.
28
97
.3
08
7.
60
37
.6
22
7.
62
47
.6
41
7.
64
37
.7
30
7.
73
37
.7
50
7.
75
27
.7
68
7.
77
17
.8
17
7.
81
97
.8
22
7.
83
67
.8
38
7.
84
08
.1
03
8.
12
39
.4
62
3.00
0.81
2.46
1.01
3.10
2.03
1.02
0.97
1.04
0.63
Harom
Figure 2.8 1H-NMR spectrum of 71e in C2D6CO.
The 1H-NMR of 71e showed the characteristic Holef peak at 6.8 ppm, while the peak
representing the methy group was found to be at 2.4 ppm. The broad peak
corresponding to the NH group appeared at 9.5 ppm. The peaks representing the
aromatic protons were found between 7.2 and 8.1 ppm.
7.58.0
64
2.5 Summary
In this chapter, starting material 1 was synthesised and photoaddition reactions were
introduced. The reactions of 1 with alkyl carboxylates, phenyl acetates and α-keto
carboxylates were all performed in a solvent mixture of acetone:water. All these
reactions were successful and resulted in moderate to good yields. These reactions
were all acetone-sensitised reactions, involving triplet sensitisation by acetone
followed by PET from the carboxylate to the triplet excited phthalimide. Subsequent
decarboxylation of the carboxy radical yields the corresponding C-radical while
protonation, intersystem crossing and C-C bond formation result in the desired
photoaddition products.
A variety of photoaddition reactions with phenyl acetates were also performed using
phthalimide as the starting material. The solvent system acetone:pH 7 buffer was
used in these cases to inhibit the natural rise in pH during irradiation, which results in
the initially formed benzylated-hydroxyphthalimidines being converted to their
potassium salts and therefore making them difficult to isolate. Using the buffered
solution it was found that the yields obtained were higher than those using 1 as
starting material.
A selection of these reactions will be used to make a comparison between the
Rayonet reactor and the microreactor, to be discussed in Chapter 6.
Several photoaddition products were then dehydrated to form the related
arylmethylenesioindolin-1-ones in good yields, which have the general structure of
the open analogues of aristolactams and will be dealt with in more detail in Chapter
4.
65
Chapter 3
66
3 Photoaddition reactions of NMP with heteratom-
containing addition partners
3.1 Introduction
This chapter deals with the reactions of 1 and substituted phthalimides with
heteroatom substituted addition partners. A series of reactions will be performed
under the conditions described in Chapter 2, including examples of sulfur-containing
addition partners and oxygen-containing addition partners. The different mechanisms
will be discussed.
A variety of N-acetylated amino acids will be synthesised and subsequently reacted
with 1, and this reaction mechanism will also be discussed. The yields and d.e’s will
be recorded, then a selection of these reactions will also be performed using
acetone/pH 7 buffer as the solvent.
67
3.2 Synthesis of starting materials
3.2.1 Synthesis of N-acetylated amino acids
Four acetyl amino acids and one acetyl dipeptide were synthesised by modifying a
procedure according to Paulmann135 by heating the desired reactant under reflux,
with acetic anhydride, in glacial acetic acid over a 3 day period. Acetyl L-t-leucine
72a was obtained in a yield of 40% following purification (Scheme 3.1). The
characteristic methyl group of the added acetyl group was found at 2.18 ppm in the 1H NMR spectrum, using CDCl3 as solvent.
72a
+glacial acetic acid
O
O O
H2N CO2H NH
CO2H
OΔ
Scheme 3.1 Experiment 32.
The same procedure was carried out using 1-aminocyclohexane carboxylic acid
(Scheme 3.2) and 72b was obtained in a yield of 95%. No purification was necessary
and the characteristic methyl group of the added acetyl group was found at 2.22 ppm
in the 1H NMR spectrum.
72b
+O
O O
H2N CO2H NH
CO2H
Oglacial acetic acidΔ
Scheme 3.2 Experiment 33.
The final two amino acids used were 2-amino-2-methylpropanoic acid and 2-amino-
2-phenylacetic acid. Experiment 36 was carried out in the same way using the
dipeptide glycyl-glycine (Scheme 3.3). The preparation of 72e was problematic.
Previous experiments resulted in a mixture of the desired product and acetyl glycine.
It appeared the product was being cleaved due to the high temperature used (145oC),
thus resulting in the formation of acetyl glycine. This was rectified by heating gently
to 120oC for a short period of time rather than heating under reflux constantly.
68
+O
O O
NH
OR
CO2HH2NR
CO2Hglacial acetic acid
Δ
72c R = C(CH3)272d R = CH(Ph)72e R = CH2C(O)NHCH2
Scheme 3.3 Experiments 34-36.
All the acetylated products were obtained in good yields, and the CH3CO peak for
each product appeared at around 2.2 ppm in the 1H-NMR spectra, as shown in Table
3.1.
Table 3.1 Synthesis of N-acylated amino acids.
compound amino acid 1H-NMR [ppm]
CH3COa yield [%]
72a L-t-leucine 2.18 40
72b 1-aminocyclohexane carboxylic acid 2.22 95
72c 2-amino-2-methylpropanoic acid 2.19 89
72d 2-amino-2-phenylacetic acid 2.26 79
72e glycyl-glycine 2.24 96 a in CDCl3/TFA
69
3.2.2 Reactions of phthalimides with sulfur-containing addition partners
N-methyl trimellitic acid imide methyl ester and dimethylsulfide were irradiated at a
wavelength of 300nm, in the previously described set-up in the Rayonet reactor
(Chapter 2), resulting in the regioselective formation of the photoproduct 73.
However, this primary product was sensitive towards dehydration and the
corresponding olefins E- and Z-74 were obtained, with the E isomer being the
predominant product.
N
O
CH3+hν
HO
73
SCH3
H3CO2C
- H2O
N
O
CH3
E-74 (85%)
H3CO2C
SCH3
SCH3H3C
H3CO2CN
O
O
CH3
N
O
CH3
Z-74 (15%)
H3CO2C+
SCH3
Scheme 3.4 Experiment 37.
In the 1H-NMR spectrum, a mixture of the E and Z isomers were present. Since the
Rf value determined by TLC analysis matched those typical for the photoaddition
products, it was concluded that 73 was formed as expected and dehydration only
occurred in the NMR tube upon standing in CDCl3. The E-74:Z-74 ratio was
determined by the 1H-NMR as 85:15.
The first peaks again represent the methyl group bound to the N-terminus. Next the
singlets representing the methyl group bound to the sulfur are observed, followed by
those representing the methoxy group. In the olefinic region the signals representing
the olefinic protons were found for both isomers. Finally in the aromatic region, the
three hydrogens from the aryl ring are accounted for.
70
N
O
CH3
S
H3CO2C
2.02.53.03.54.04.55.05.56.06.57.07.58.08.5 ppm
1.
60
3
2.
17
3
2.
53
42
.5
71
3.
31
3
3.
62
43
.9
43
3.
95
53
.9
71
3.
98
13
.9
88
4.
67
6
6.
09
1
6.
27
3
7.
60
07
.6
21
8.
08
58
.1
88
8.
19
08
.2
09
8.
21
08
.2
72
8.
27
68
.2
93
8.
29
78
.4
85
6.46
1.95
0.62
2.49
2.49
0.59
3.29
1.00
0.79
0.18
0.17
0.62
1.15
0.83
0.94
NCH3
E
Z
ZZ
Holef.Harom.
EZ
EE
E + Z
Z
OCH3
SCH3
Figure 3.1: 1H-NMR spectrum of E- and Z-74 in CDCl3.
Additionally, N-phthalimido-glycine methyl ester was reacted with dimethylsulfide
by irradiating at 300nm, resulting in the formation of 75 (Scheme 3.5). Again, the
primary product 75 was sensitive to dehydration and as a result, 75 was isolated with
the dehydration products 76. The E isomer was again found to be the main isomer for
the dehydration products. The 75:E-76:Z-76 ratio was determined by 1H-NMR as
61:23:16.
71
+hν
- H2O
N
OE-76 (23%)
SCH3
SCH3H3C
N
OZ-76 (16 %)
+
SCH3
N
O
O75 (61%)
N
O
SHO
CO2CH3 CO2CH3
CH3
MeCN
CO2CH3 CO2CH3
Scheme 3.5: Experiment 38.
Table 3.2: Photoadditions of dimethylsulfide to N-methyl trimellitic acid imide
methyl ester and N-phthalimido-glycine methyl ester.
compound time [hr] conversion [%] yield [%] compositionb
73/74a 24 100 47 73 = 0 E-74 = 85 Z-74 = 15
75/76a 4.5 100 74 75 = 61 E-76 = 23 Z-76 = 16 a identified as corresponding olefin pair in the 1H-NMR, b determined by 1H-NMR integration.
In the case of thioethers (Scheme 3.6), both electron transfer and deprotonation are
reversible and as a consequence, a quantity of the starting materials are regenerated
before they can undergo addition. Because of this, prolonged irradiation times are
required for the reaction to go to completion.
N
O
O
CH3 + +CH3S
*
R SR
H HPETS
HH
SR
+
Scheme 3.6 Mechanistic key-steps for the addition of thioethers.
In experiment 37, N-methyl trimellitic acid imide methyl ester was reacted with
dimethylsulfide resulting in the formation of the photoproduct 73. This reaction was
regioselective as addition exclusively occurred at the carbonyl group para to the
72
CO2Me group. Its preferred formation over the meta-product is in line with the
literature,36 which offers an explanation on the basis of the differences in spin
densities in the corresponding imide radical anions. The spin density is significantly
higher at the imide para-carbon atom than for the meta-carbon atom, so the chance
of para-coupling is therefore much higher.
N
O
CH3
+
hν
HO
73
SCH3
H3CO2C
SCH3H3C
H3CO2CN
O
O
CH3
N CH3H3CO2C
H3CO2CN
O
O
CH3
H3CO2CN
O
O
CH3
para
meta
+ SCH3H3C
O
HOS
CH3
PET
+ .
+
Scheme 3.7 Proposed mechanism for experiment 37.
Also mentioned previously is the fact that a mixture of the E and Z isomers for 74
were formed, as determined by 1H-NMR. This dehydration must have occurred in the
NMR tube, as CDCl3 was used as the solvent, which becomes slightly acidic due to
the formation of DCl. Photoaddition products are known to be sensitive towards
hydrolysis, as the driving force of this reaction is the potential gain in conjugation
with the aromatic ring. In experiment 38, the photoproduct 75 also underwent
dehydration in the NMR tube to give a mixture of E and Z olefins 76.
For photoadditions involving heteroatom-substituted carboxylates, two mechanistic
pathways are possible (Scheme 3.8):
1. Electron transfer from the carboxylate anion to the excited phthalimide
yielding unstable carboxy radicals and
2. Electron transfer from the neutral heteroatom resulting in the formation of its
radical cation. This mechanism is known for α-trimethylsilylmethyl-
73
substituted analogues where the TMS-cation functions as activating and
leaving group.28c
CO2XR
Donor1 Donor2
N
O
O
CH3
3 *
+ N
O
O
CH3
ET
CO2XR
Radical cation
CO2XR
Carboxy radical
+ Or
+
Scheme 3.8 Competitive scenario for heteroatom substituted carboxylates.
3.2.3 Reaction of NMP with oxygen-containing addition partner
As an example of a reaction of NMP with an oxygen-containing addition partner, in
experiment 31 a methoxy-ethylene group was introduced (Scheme 3.9), but even
after prolonged irradiation of 16 hours a conversion of just 33% was achieved. Based
on the conversion the yield was found to be 24%.
N
O
O
CH3 + N CH3
O
HO
H3COCO2K
OCH3
77 (24%)1
hν
acetone / water
Scheme 3.9 Experiment 39.
In the 1H-NMR of 77 (Figure 3.2), the CH2 bridge is found between 2.20 and 2.48
ppm. The two hydrogens are split by each other and by the neighbouring CH2O
group. The singlet representing the N-methyl group was found at 2.85 ppm. The
triplet at 3.0 ppm represents the CH2 group bound to the methoxy group. The
methoxy group was observed as a singlet at 3.16 ppm, the OH group at 4.14 ppm as a
sharp singlet. The four aromatic protons were found between 7.4 and 7.6 ppm.
74
N CH3
O
HO
OCH3
2.53.03.54.04.55.05.56.06.57.07.5 ppm
2.
24
82
.2
65
2.
40
52
.4
23
2.
44
02
.4
59
2.
47
62
.8
42
3.
08
23
.0
99
3.
11
53
.1
60
4.
13
6
7.
39
37
.3
99
7.
40
97
.4
12
7.
41
47
.4
17
7.
42
87
.4
33
7.
52
5
1.03
1.03
2.98
2.05
3.00
1.00
1.01
3.00
OH CH2
NCH3
OCH3
CH2Harom
CH2
Harom
Figure 3.2 1H-NMR spectrum of 77 in CDCl3.
Due to the low conversion of starting material (1) of only 33% after 16 hours
irradiation, it was assumed, that in the particular case of 77, an alternative simple
decarboxylation pathway (CO2H/H exchange) dominated in which the NMP acted as
a catalyst.34b Alternatively, a non-productive electron transfer from the ether-group
may have caused this drop in conversion.38a
The proposed mechanism for β-oxoalkyl-substituted carboxylates is depicted in
Scheme 3.10. Product formation can only be explained by electron transfer from the
carboxylic acid function to the excited phthalimide chromophore. Subsequent
decarboxylation and C-C formation yields the observed addition products. This
crucial key-step is in agreement with the lower oxidation potential of carboxylates
compared to the ether oxygen.
7.47.57.6 ppm
2.32.42.5 ppm
75
N
O
O
CH3 + O
*
R
OR O
R
PETCO2
PETO
CO2
CO2CO2
+OR O
R CO2CO2
H-H+
+
Scheme 3.10 Mechanism of addition of β-substituted heteroatom in the oxygen
case.
Although reactivity prevailed for the β-oxoalkyl-substituted carboxylate, the
efficiency of this reaction was very low, based on both the yield and required
irradiation time. Possibly, hydrogen abstraction from the α-position of the oxygen
atom may compete with electron transfer mediated decarboxylation (Scheme 3.11).
Similar hydrogen-abstractions are known for irradiations involving simple
dialkylethers.24,26
α-H-abstraction
- CO2O O
OR
- H+O O
OR
OR
PET decarboxylationH
α O O
OR
PET
Scheme 3.11 Alternative mechanisms for the β-oxoalkyl-substituted carboxylates.
It should be noted here that despite their low yields the β-oxoalkyl-based
photoaddition products are only available via the photodecarboxylative addition
protocol. Neither dialkylethers nor trimethylsilylalkyl ethers yield similar products.
3.2.4 Photodecarboxylative addition of N-protected amino acids to NMP
NMP (1) was reacted with twelve N-protected amino acids as shown in Scheme 3.12.
These reactions were performed over a period of 1-8.5 hr and gave yields ranging
from 6-92%. Compounds 78c, d, f, g, i, and j gave diastereoisomeric mixtures with
d.e.’s ranging from 8-56%, which are shown in Table 3.3.
76
A selection of these reactions were also performed in acetone/pH 7 buffer to
investigate the effect, if any, this had on the reactions with particular interest in the
d.e.’s obtained. This solvent mixture was known to clean up reactions as
demonstrated in our research group.136 The results are also shown in Table 3.3
below.
N
O
O
CH3
R1
O
R2
N
O
CH3
HOHN
acetone / water oracetone / pH7 buffer
NH
CO2K
R2
R1
O+
N-protectedamino acids
hνR3R3
1 78a-l
Scheme 3.12 Experiments 40-56.
Table 3.3 Photoadditions of N-protected amino acids to 1.
compound R1 R2 R3 time [hr] yield
[%] d.e. [%]
78a CH3 H H 3.5 19
78b CH3 CH3 CH3 4.5 83
3.5 52 52 78c CH3 i-Pr H
5a 32a 24a
3 26 24 78d CH3 i-Bu H
4a 36a 22a
78e CH3 s-Bu H 3 78 See below
78f CH3 t-Bu H 8.5 6 48
78g CH3 Ph H 2 92 8
78h t-BuCO H H 1 74
2 65 34 78i t-BuCO CH3 H
4a 81a 10a
3 34 36 78j t-BuCO PhCH2 H
4a 36a 30a
78k CH3 C5H10 3 80
1.5 19 78l (C13H10)CH2O H H
3a 20a a reaction performed in acetone / pH7 buffer
77
In experiment 46, a total of four stereoisomers of the product 78e were obtained as
there are three chiral centres present. One chiral centre is fixed due to the addition
partner used, while the other two are determined by the C-C bond formation, which
results in four different isomers and their respective enantiomers being formed in
ratios of 11:12:25:52 (see experimental section). Three products 78a,b and h showed
no visible formation of isomers in the resulting 1H-NMRs. For the remaining
products, the d.e. ranged from 6-50%.
1.52.02.53.03.54.04.55.05.56.06.57.07.58.08.5 ppm1
.0
08
1.
53
2
2.
08
9
2.
99
6
7.
48
37
.4
86
7.
50
17
.5
04
7.
51
97
.5
22
7.
55
77
.5
60
7.
57
67
.5
79
7.
59
37
.5
96
7.
60
47
.6
05
7.
62
37
.6
38
7.
64
07
.6
56
7.
65
87
.6
60
2.95
3.03
3.16
3.00
1.02
1.11
0.93
0.96
0.86
0.67
N
O
CH3
HONH
O
NCH3
CH3
CH3CO
OH
NH
Harom
Figure 3.3 1H-NMR spectrum of 78b in C2D6CO.
A representative 1H-NMR spectrum for N-acetylated photoaddition products is
shown using photoaddition product 78b as an example in Figure 3.3. The methyl
group at the N-terminus is found as a singlet at 3.00 ppm. The two singlets at 1.00
and 1.53 ppm represent the two methyl groups at the bridge between the former
phthalimide and the addition partner. The acetyl group is found as a singlet at 2.09
ppm. The OH group was found as a broad peak at ~8.7 ppm, while the NH group
was found at 7.7 ppm. In the aromatic region the peaks representing the four
aromatic protons can be found between 7.5-7.7 ppm.
7.67.77.8 ppm
78
1.52.02.53.03.54.04.55.05.56.06.57.07.5 ppm
1.
21
81
.2
36
1.
25
41
.3
67
1.
40
91
.4
32
1.
44
9
2.
00
3
2.
89
33
.0
32
4.
34
74
.4
53
5.
51
45
.5
34
5.
66
8
6.
03
5
6.
41
57
.5
08
7.
51
17
.5
24
7.
52
77
.5
29
7.
54
27
.5
45
7.
54
87
.5
60
7.
56
37
.5
84
7.
58
87
.6
00
6.25
3.30
3.00
0.99
0.57
0.51
0.27
0.27
0.99
1.02
1.97
N
O
CH3
HONH O
O
Harom OH OH NHNH
Minor Major
Major and Minor
NCH3t-Bu minor
CH3 minorCH3 major
t-Bu major
Figure 3.4 1H-NMR spectrum of 78i in C2D6CO.
A representative 1H-NMR spectra for N-BOC-protected photoaddition product 78i is
shown in Figure 3.4. It could not be determined which diastereoisomer (like or
unlike) was the major/minor component. The N-terminus methyl groups were found
as singlets at 3.03 ppm. Two doublets representing the CH3(CH) groups were found
at 1.00 and 1.44 ppm respectively. Two singlets representing the t-Bu groups were
found at 1.37 and 1.41 ppm respectively. The CH groups for both appeared as a
multiplet at 4.4 ppm. The OH groups were found as singlet peaks at ~5.7 and 6.4
ppm. The NH groups were also found in that region at ~5.5 and 6.0 ppm. In the
aromatic region the peaks representing the eight aromatic protons can be found
between 7.51 and 7.71 ppm.
In contrast to irradiations involving N,N-dialkylated amino acids, which solely give
photoreduction or solvent-trapping, N-acylation of amino acids restored
photoreactivity and the corresponding addition products were obtained in moderate
to high yields after short irradiation times. This suggests that the crucial electron
transfer step occurs primarily from the carboxylate function as supported by the
oxidation potentials (EOx. CONR ≥ EOx. CO2-). The difference of the oxidation
1.01.21.4 ppm
79
potentials of the competing donors is, however, rather small (N-methylacetamide:
EOx. = 1.81 V in MeCN137 and acetate: EOx. = 1.54 V in MeCN vs. SCE127).
As for simple alkyl and oxygen-containing carboxylates, photoinduced electron
transfer from the carboxylate function to the excited phthalimide yields an unstable
carboxy radical, which rapidly undergoes decarboxylation to the corresponding
carbon centred radical (Scheme 3.13). Subsequent C-C bond formation yields the
isolated photoproducts.
N
O
O
CH3 + NH
*
CO2
NH
O
O
PETCO2
PETCONHO
O
NH
O
NH
O
O
O
NH
O
-CO2
-CO2
+
Scheme 3.13 Mechanism of amide-containing carboxylates.
Analogue photocyclisations of phthaloyl dipeptides have been described by the
groups of Yoon/Mariano138 and Griesbeck/Oelgemöller.139 Both groups favour
different PET scenarios. Whereas Yoon and Mariano postulated electron transfer
from the amide linker (Scheme 3.14), Griesbeck and Oelgemöller suggested electron
transfer from the carboxylate function instead (Scheme 3.15). The latter scenario is
supported by successful macrocyclisation of dipeptides with terminal ω-amino acid.
In those cases, the remote position of the amide group would not allow rapid
elimination of carbon dioxide.
80
N
O
ON
Ohν
H
CO2
CO2H
PETamideN
O
NO CO2HO
N
O
NOOH
C-C1.
2.
~H+
+
N
O
NO
HO
Scheme 3.14 Proposed mechanism for the photocyclisation of N-phthalimido-
glycine sarcosine by Yoon and Mariano
N
O
ON
O
H
CO2
CO2
N
O
NO CHO2O
N
O
NOO
C-C1.
2.N
O
NO
HO
PETCO2
Scheme 3.15 Proposed mechanism for the photocyclisation of N-phthalimido-
glycine sarcosine by Griesbeck and Oelgemöller
By comparing the crude 1H-NMR spectra, the products formed in experiments 43,
45, 51, 53 and 56, perfomed in acetone/pH 7 buffer, were shown in general to have
no significant improvement on the previous reactions in terms of purity. In the case
of 78i, the yield was improved considerably, from 65% to 81%, however the d.e. was
found to decrease from 34% to 10%. In fact the resulting products all had lower
d.e.’s than the previous products obtained.
81
Using Ligand Repulsive Energies, ER, (in kcal mol-1)140 it was attempted to explain
the diastereoselectivity obtained in products 78c, d, f and g. In contrast to other steric
parameters, these ER values are free of any resonance effects and have been
demonstrated to provide reliable steric parameters for ligands in organometallic
systems. They have been used in this case as it was found that they provide the most
consistent and generally useful measures of relative steric sizes.140 Results are shown
in Table 3.4 below.
N
O
O
CH3
CH3
O
N
O
CH3
HOHN
acetone / waterNH
CO2KH3C
O+
N-acetylatedamino acids
hν
1 78c,d,f,g
R R
Scheme 3.16 Reaction of 1 with N-acetylated amino acids.
Table 3.4 Comparison of ER values and d.e.’s obtained for 78c,d,f and g.
compound R ER [kcal/mol]
d.e. [%]
78g Ph 33 8 78d i-Bu 44 24 78c i-Pr 57 52 78f t-Bu 59 48
It is clear there is indeed correlation between increased steric bulk and a higher d.e.
value, despite the minor anomaly between the i-Pr and t-Bu groups. As there is only
a slight difference between their respective ER values, it is not surprising that the d.e.
values would also be similar. These results imply that anything larger than an i-Pr
group, such as a t-butyl group, has no further effect on the d.e values.
82
The same was attempted for both N-BOC protected amino acids, 78i and j (Scheme
3.17), and the results are shown in Table 3.5.
N
O
O
CH3
O
O
N
O
CH3
HOHN
acetone / waterNH
CO2KO
O
+
N-BOC protectedamino acids
hν
1 78i, j
R R
Scheme 3.17 Reaction of 1 with N-BOC protected amino acids.
Table 3.5 Comparison of ER values and d.e.’s obtained for 78i and j.
compound R ER [kcal/mol]
d.e. [%]
78i CH3 17 34 78j PhCH2 42 36
Although the difference in the d.e.’s obtained was only marginal, whereas the
difference in the ER values was quite significant, it did however follow the trend i.e.
the lower the ER value, the lower the d.e. value. It can therefore be concluded that the
Ligand Repulsive Energies can in fact be used as a guide in determining the expected
d.e.’s of the desired products.
83
3.3 Summary
In this chapter, reactions of 1 and substituted phthalimides with heteroatom with
heteroatom-containing addition partners were investigated. Following the successful
reactions of substituted phthalimides N-methyl trimellitic acid imide methyl ester and
N-phthalimido-glycine methyl ester with dimethylsulfide, 1 was successfully reacted
with 3-methoxypropanoic acid.
A variety of N-acetylated amino acids were successfully synthesised and
subsequently reacted with 1, with low to moderate d.e’s obtained. Performing the
selected reactions of 1 with N-acetylated amino acids in solvent system acetone:pH 7
buffer seemed to slightly lower the d.e values obtained. Ligand Repulsive Energies
were also used to discuss the d.e’s obtained, and a correlation was found between the
bulk of the substituent groups on the N-acetylated amino acids and size of the d.e
values obtained.
These reactions will also be used to make a comparison between the Rayonet reactor
and the microreactor as a selection of these will be performed in the microreactor and
discussed in Chapter 6.
84
Chapter 4
85
4 Synthesis of aristolactams using phthalimide derivatives
as precursors
4.1 Introduction
Aristolactams are a family of naturally occurring compounds possessing a
phenanthrene chromophore, and are known to possess a wide variety of biological
activity. For example, aristolactams and related compounds act as antibacterial
agents, immunostimulants and display cytotoxic activity against various cancer cell
lines and so may be useful for further development as pharmaceuticals, as outlined in
Chapter 1.
Several compounds have been synthesised thermally by Couture et al., however in
this chapter, an attempt to synthesise aristolactams by photochemical means is
discussed. One of the benefits of this method, if successful, is the availability of a
vast array of cheap starting materials possessing a wide range of substituents, ideal
for constructing structurally diverse derivatives. A three-step procedure will be used,
which involves an initial photoaddition reaction, dehydration of the resulting
photoproduct and eventual ring closure by irradiation in benzene.
86
4.2 Synthesis of starting materials
4.2.1 Synthesis of dimethoxy-N-methylphthalimide and its precursors
The synthesis of dimethoxy-NMP 79d and dimethoxyphthalimide 79e were realised
in a four-step procedure (Scheme 4.1).
OH3CO
H3CO
O
H3CO
H3CO
CO2H
CO2H
OH3CO
H3CO
O
O
NH3CO
H3CO
O
O
R
10% Na2CO3 solutionKMnO4
Ethanol1 week
Acetic anhydride
1 hr
N-Methylformamide or Formamide
79b (76%)
79c (90%)79d R =CH3 (84%)79e R = H (72%)
Δ
2 hrΔ
H3CO
H3CO
CO2H
Conc. HClreflux ~7 hrs
paraformaldehyde
79a (46%)
Scheme 4.1 Experiments 57-61.
In the first step, 79a is synthesised by heating paraformaldehyde and veratric acid
under reflux in concentrated HCl for 6 hr. When the pH of the solution was adjusted
to pH 7 the product formed as a precipitate (46% yield). 79a was then stirred for a
week at r.t. with 1.1 equivalents of KMnO4 and 2.2 equivalents of a 10% Na2CO3
solution. Following work-up, the precursor 79b was obtained in a yield of 76%. In
the second step 79b was heated under reflux in acetic anhydride for 1 hr, after which
time the solvent was removed by distillation and the anhydride 79c was obtained in a
yield of 90%. This was then used in the final step of the synthesis of 79d, which
involved heating 79c under reflux in N-methylformamide for 2 hr, resulting in
crystals being formed upon cooling, which were filtered to give 79d in 84% yield.
87
The overall yield, throughout the final three steps, was calculated to be 40%. The
characteristic N-methyl group was found at 3.14 ppm in the 1H NMR spectrum in
CDCl3.
For the synthesis of 79e, the first three steps of the procedure were repeated, while
the last step consisted of heating 79c under reflux in formamide. The final step
produced 79e in a pure yield of 72%.
4.2.2 Iodination of di- and trimethoxyphenylacetic acids
The synthesis of iodo-dimethoxyphenylacetic acid 81a and iodo-
trimethoxyphenylacetic acid 81b were achieved with a straightforward one step
procedure (Scheme 4.2).
H3CO
H3COCO2H
H3CO
H3COCO2H
II2, CF3CO2Ag
DCM
R R
80a = H80b = OCH3
81a = H (76%)81b = OCH3 (63%)
Scheme 4.2 Reaction scheme for synthesis of 81a and 81b.
Following a method by Janssen and Wilson,141 the iodination of both 80a and 80b
was performed by stirring the desired acid with silver trifluoracetate (1 equiv.) and
iodine (1 equiv.) in chloroform overnight. Following recrystallisation the pure yield
for 81a was found to be 76% and in the case of 81b the yield was 63%.
4.3 Formation of aristolactams
4.3.1 Formation of aristolactam skeleton
As an alternative to thermal methods, the aristolactam skeleton 82c was successfully
formed in a three-step procedure using PDC addition (as seen in Chapter 2) of 2-
88
iodophenylacetic acid to 1 as the first step. This resulted in 82a being obtained in a
yield of 51%.
N
O
HO
CH3
I
N CH3
O
I
N CH3
O
DCM
HCl benzene
hν
82a 82b (90%) 82c (24%) Scheme 4.3 Experiments 64-66.
The second step involved 82a undergoing a dehydration reaction to form 82b which
was obtained in a yield of 90% as the single Z-isomer. The final step was an
oxidative dehydrohalogenation using benzene as the solvent. The iodo group was
cleaved during irradiation which effected the formation of the aristolactam skeleton
82c which was obtained in a yield of 24% after performing column chromatography.
Interestingly, the crude 1H-NMR showed the presence of both isomers. As the
intermediate 82b, formed by hydrolysis resulted in solely the E-isomer being formed,
which is the “reactive geometry” needed, E-Z isomerisation (Scheme 4.4) must have
occurred during the final step. This could explain the low yield of the desired
product.
89
N CH3
O
I
N CH3
O
I
E-isomerZ-isomer
hν
N CH3
O
H+ I
N
O
CH3
N
O
CH3
H
- HDecomposition
C-I cleavage
C-I cleavage
82c
N CH3
O
Scheme 4.4 E-Z isomerisation of 82b resulting in the formation of 82c.
The isomerisation competes with the cyclisation reaction, generating a radical which
results in the eventual ring closure forming the aristolactam skeleton.
Having successfully synthesised the skeleton, the next step was to attempt to
synthesise several substituted aristolactams.
90
4.3.2 Formation of substituted aristolactams with iodo-precursors
In experiments 67 and 70, 1 was irradiated in the presence of both 81a and 81b to
form 83 and 84 in yields of 8% and 33% respectively. In both cases, even after
prolonged irradiation, both 1 and the acid partner were still present in the crude 1H-
NMR spectrum.
N
O
Oacetone / water
+N
O
HOCO2K
H3CO
OCH3
CH3
OCH3
RI
I
R OCH3
CH3
hν
83 R = H84 R = OCH3
81a R = H81b R = OCH3
1
Scheme 4.5 Experiments 67-72.
Following purification, the products were successfully isolated. To ensure that the
irradiation period was not the problem, both reactions were repeated twice with
longer irradiation periods and, as seen in Table 4.1 below, extending the irradiation
time did little to improve the overall yields obtained for either 83 or 84.
Table 4.1 Varying irradiation times for the synthesis of 83 and 84.
compound R time [hr] yield [%]
83 H 8 8 83 H 16.5 9 83 H 31 11 84 OCH3 13 33 84 OCH3 16.5 35 84 OCH3 31 35
A potential reason for the low yields could be that the bulky iodo group is simply
blocking the C-C bond formation. Taking the iodo acid 81b as an example, shown in
Figure 4.1 as a “ball and stick” model for comparison, this idea is investigated.
91
Figure 4.1 “Ball and stick” model of 81b created using Chem3D Ultra 8.0
software.
As seen from the “space filling” model of 81b shown in Figure 4.2, the iodo
substituent (shown in pink) is a very large group which may, due to its sheer size,
simply not allow the two newly formed radicals to come into contact because of
steric hindrance. For both 81a and 81b, the iodo group is located beside the
carboxylic acid substituent which undergoes the required PDC process, and hence
the radical is subsequently in close proximity to the bulky iodo function.
Figure 4.2 “Space filling” model of 81b created using Chem3D Ultra 8.0
software.
.
92
The second dehydration step was performed with 84 as shown in (Scheme 4.6)
below.
N
O
HO
CH3
I
N CH3
O
IDCM
HCl
84 85
OCH3
OCH3H3CO
H3CO
H3CO OCH3
Scheme 4.6 Experiment 73.
In experiment 73, the starting material 84 was converted by dehydration to 85.
Following work-up, both isomers were formed as seen in the 1H-NMR and the ratio
calculated from the integration of the olefinic peaks to be 17:83, with the E-isomer
found to be the major isomer. This product was then used in the final step to make
the desired aristolactam as seen below in (Scheme 4.7).
N CH3
O
I
N CH3
O
benzene (DDQ)
hν
85 86
H3CO
H3CO OCH3
H3CO
H3COOCH3
Scheme 4.7 Experiments 74 and 75.
93
As an investigative monitoring study, 85 was dissolved in benzene-d6 and placed in
an NMR tube which was then set up in the Rayonet reactor and irradiated. For the
first hour 1H-NMR spectra were obtained every 15 min by stopping the reaction,
obtaining the 1H-NMR, returning the NMR tube to the Rayonet reactor and then
commencing irradiation. From then on, 1H-NMR’s were continued to be obtained
hourly up until 19 hr, when the reaction was undisturbed until 36 hr and a final 1H-
NMR obtained. In the first few hours, E-Z isomerisation was clearly occurring as
indicated by 1H-NMR (Figure 4.3 and Figure 4.4).
N
O
CH3
NCH3OCH3
OCH3H3CO
H3CO
I
3.54.04.55.05.56.06.57.07.5 ppm2
.8
61
3.
01
1
3.
16
83
.2
30
3.
68
93
.7
38
3.
76
13
.7
97
6.
06
76
.4
27
6.
44
86
.7
54
6.
75
66
.7
73
6.
77
56
.7
93
6.
87
56
.8
77
6.
89
46
.8
95
6.
91
26
.9
94
7.
00
37
.0
05
7.
01
17
.0
13
7.
02
27
.0
24
7.
02
97
.0
46
7.
06
47
.0
73
7.
07
67
.0
93
7.
09
5
0.70
2.89
0.67
3.00
0.65
3.17
0.93
2.96
0.96
0.48
0.69
1.25
1.08
0.65
0.25
0.54
1.03
0.28
1.07
E + Z
Figure 4.3 Initial 1H-NMR of experiment 74 obtained at 0 hr.
94
N
O
CH3
NCH3
OCH3
OCH3H3CO
H3CO
I
E + Z
3.03.54.04.55.05.56.06.57.07.5 ppm
2.
86
2
3.
01
1
3.
16
83
.2
28
3.
68
93
.7
38
3.
76
13
.7
96
6.
06
86
.4
29
6.
44
76
.7
53
6.
75
66
.7
72
6.
77
56
.7
91
6.
87
56
.8
77
6.
89
46
.8
96
6.
91
26
.9
14
6.
99
26
.9
94
7.
00
27
.0
04
7.
00
57
.0
10
7.
01
27
.0
22
7.
02
47
.0
26
7.
02
97
.0
31
7.
07
27
.0
75
7.
09
17
.0
94
2.52
3.00
2.52
3.11
2.78
3.37
2.89
3.10
0.99
1.71
0.75
1.31
1.14
1.42
0.69
0.69
1.11
0.95
1.38
0.38
N
O
CH3
H3COOCH3
OCH3
I
E Z
Figure 4.4 1H-NMR of experiment 74 obtained after 15 min.
The first signs of the aristolactam being formed occurred after 3 hr (Figure 4.5) and
in the final 1H-NMR (Figure 4.6) the distinctive aromatic protons of the product can
clearly be seen although it is not entirely pure.
95
2.53.03.54.04.55.05.56.06.57.07.58.08.59.09.5
3.796
3.838
3.860
6.069
6.431
6.448
6.449
6.754
6.757
6.773
6.776
6.786
6.792
6.795
6.877
6.880
6.896
6.898
6.915
6.917
6.996
7.012
7.014
7.020
7.022
7.024
7.025
7.030
7.033
7.074
7.077
7.093
7.095
7.111
7.114
7.132
7.238
7.258
7.304
7.306
7.323
7.824
7.826
7.828
7.838
7.843
7.845
7.847
7.857
7.859
7.861
2.27
3.00
2.33
3.17
2.35
3.23
2.69
3.06
0.60
0.58
0.96
1.52
0.75
1.18
1.44
1.40
1.15
0.94
1.78
0.16
0.15
ppm
N CH3
O
H3CO
H3COOCH3
E + Z
N
O
CH3
NCH3
OCH3
OCH3H3CO
H3CO
I
*
*Harom
Figure 4.5 1H-NMR of experiment 74 obtained after 3 hr.
Harom.Harom.
3.03.54.04.55.05.56.06.57.07.58.08.59.0 ppm
3.
00
73
.0
49
3.
17
63
.1
93
3.
23
13
.2
52
3.
25
93
.2
67
3.
33
93
.3
44
3.
35
93
.3
74
3.
40
73
.4
13
3.
45
23
.4
69
3.
52
73
.6
64
3.
67
83
.6
86
3.
70
33
.7
20
3.
73
43
.7
52
3.
75
73
.7
60
3.
77
63
.7
80
3.
79
13
.8
06
3.
82
03
.8
35
3.
85
73
.8
66
3.
87
23
.8
80
3.
88
63
.8
94
3.
90
66
.0
66
6.
46
36
.7
73
6.
78
06
.7
85
6.
89
77
.0
00
7.
02
07
.1
09
7.
12
87
.2
30
7.
24
97
.4
24
7.
44
47
.8
39
7.
99
78
.0
15
9.
21
69
.2
37
0.66
3.00
3.03
2.16
3.36
3.66
1.48
2.56
3.25
3.53
3.93
2.57
4.33
3.66
3.60
0.96
1.17
3.23
1.83
3.02
1.32
1.92
2.10
1.56
1.09
0.97
N
O
CH3
OCH3
H3CO
H3CO
Figure 4.6 Final 1H-NMR of experiment 74 obtained after 36 hr.
96
In an attempt to improve the purity of the aristolactam, in a second monitoring study,
85 was again placed in an NMR tube in solvent benzene-d6, and to encourage ring
closure the oxidant DDQ was added periodically throughout the reaction. Again a 1H-NMR was obtained after the first and second hour, and then for every 2nd hour
until 22 hr, the final 1H-NMR was obtained after 25 hr.
N CH3
O
H3CO
H3COOCH3
E + Z
N
O
CH3
NCH3
OCH3
3.03.54.04.55.05.56.06.57.07.58.08.59.0 ppm
2.
85
63
.0
05
3.
05
73
.1
75
3.
22
63
.2
52
3.
25
83
.2
67
3.
47
93
.5
25
3.
58
63
.6
64
3.
67
93
.6
86
3.
73
33
.7
58
3.
79
13
.8
35
3.
84
33
.8
72
3.
88
33
.8
93
6.
06
86
.4
26
6.
44
76
.7
59
6.
77
56
.7
79
6.
78
36
.7
94
6.
79
76
.8
80
6.
88
36
.8
99
6.
90
27
.0
13
7.
01
57
.0
32
7.
03
47
.0
73
7.
08
97
.0
92
7.
23
47
.2
54
7.
29
47
.2
96
7.
29
87
.3
15
7.
82
87
.8
30
7.
83
27
.8
40
7.
84
27
.8
45
7.
84
67
.8
49
7.
85
17
.8
61
2.78
3.00
0.42
2.82
3.08
0.70
0.51
0.50
0.50
0.43
3.17
3.17
3.05
3.08
0.91
0.51
0.42
0.95
2.05
2.14
1.40
1.25
1.21
1.07
1.13
1.86
0.14
0.12
OCH3H3CO
H3CO
I
*
*Harom
Figure 4.7 1H-NMR of experiment 75 after 1 hr with desired product 86 visible.
97
N
O
CH3
OCH3H3CO
H3CO
I
N
O
CH3
H3COOCH3
OCH3
I
NCH3
OCH3
3.03.54.04.55.05.56.06.57.07.58.08.59.0 ppm
2.
85
53
.0
03
3.
05
53
.1
81
3.
22
63
.4
84
3.
52
43
.5
89
3.
68
73
.7
34
3.
75
93
.7
92
3.
83
73
.8
69
3.
90
36
.0
73
6.
42
86
.4
44
6.
45
06
.4
51
6.
76
56
.7
74
6.
77
96
.7
93
6.
79
56
.8
74
6.
88
66
.9
06
6.
90
86
.9
24
7.
00
17
.0
18
7.
02
07
.0
36
7.
03
87
.0
70
7.
07
37
.0
89
7.
09
17
.1
07
7.
11
07
.2
30
7.
24
97
.2
90
7.
30
97
.4
55
7.
45
87
.4
76
7.
84
37
.8
51
7.
86
17
.8
67
7.
87
08
.0
37
8.
05
49
.2
23
9.
24
29
.2
43
2.77
3.00
1.67
2.89
3.14
0.90
1.62
1.80
1.21
2.80
3.76
3.43
3.23
2.05
2.37
1.58
0.96
2.59
2.65
1.25
1.76
1.53
1.32
1.36
1.44
0.69
2.08
0.58
0.54
E + Z
Figure 4.8 1H-NMR of experiment 75 after 4 hr.
E-Z isomerisation was also seen to occur during this reaction, as illustrated in Figure
4.7 and Figure 4.8, however this reaction progressed more efficiently with the
desired product being visible after 1 hr (Figure 4.7). After 25 hr the aristolactam was
found to be quite pure albeit with a small amount of starting material still visible
(Figure 4.9).
98
3.03.54.04.55.05.56.06.57.07.58.08.59.0 ppm
2.
83
02
.9
73
3.
10
9
3.
61
23
.6
60
3.
69
73
.7
24
3.
74
83
.8
22
3.
92
8
6.
06
3
6.
28
0
6.
64
8
7.
40
17
.4
19
7.
42
17
.4
39
7.
94
57
.9
63
8.
98
79
.0
07
0.66
0.84
3.00
4.21
1.31
1.41
0.88
1.06
3.40
3.38
0.27
1.07
1.20
1.59
1.09
1.00
N
O
CH3
OCH3
H3CO
H3CO
Harom. Harom.NCH3
OCH3
Figure 4.9 Final 1H-NMR of experiment 75 obtained after 25 hr showing
formation of 86.
The iodinated addition partners 81a and 81b were chosen specifically with the final
step of the procedure in mind. The iodo group is known to act as a very good leaving
group which should guarantee ring closure occurring. Paradoxically, the iodo group
seemed to be preventing the initial photoaddition reaction from proceeding.
The result obtained in experiment 75 was therefore very exciting as it was hoped that
DDQ could be used to drive the reaction forward in the final cyclisation step without
the presence of the bulky iodo group which seemed to be causing the insolubility
issues. Electrocyclisation does not occur without the iodo being present, as the
positions are too far away from each other due to ineffective overlapping of the
extremes of the hexatriene system as postulated by Castedo et.al.66 It was thought
that DDQ, as a powerful oxidising agent, might help to overcome this.
99
4.3.3 Formation of substituted aristolactams with non-iodo-precursors
To investigate whether the initial photoaddition reactions would go to completion
more readily without the presence of the iodo group, photoaddition reactions of 79d
and commercially available potassium di-/trimethoxyphenylacetates 87a,b were
performed as outlined in Scheme 4.8 below.
N
O
Oacetone / water
+N
O
HOCO2K
H3CO
OCH3
CH3
OCH3
R
R OCH3
CH3
hνH3CO
H3COH3CO
H3CO
88 R = H89 R = OCH3
79d 87a R = H87b R = OCH3
Scheme 4.8 Experiments 76 and 77.
While there were some further solubility issues with the starting material 79d in
experiment 76, the results as shown in Table 4.2 were far superior to those obtained
previously with the starting material 1 and the related iodo-compounds.
Table 4.2 Yields for experiments 76 and 77.
compound R time [hr] yield [%]
88 H 8 21 89 OCH3 8 97
In experiment 76 the reagents, 79d and 87a, were initially a little difficult to dissolve,
however this was solved by sonicating and heating the solution. During irradiation, a
precipitate was visible throughout the reaction and after irradiating for 8 hr, the
reaction was stopped and the precipitate found to be a mixture of 79d and 87a. This
was rather disappointing, however the reaction was worked up regardless and the
crude 1H-NMR showed the desired product had been formed. Following purification,
the yield for 88 was determined to be 21%.
100
In experiment 77, using 79d and 87b, there were no solvation issues with 79d and
both reagents went into solution readily. In this case, a precipitate was also visible
towards the end of the 8 hr irradiation period, however when isolated, the precipitate
was identified as the target product in an 89% yield. Following work-up, the crude 1H-NMR also showed the presence of the desired product, which after purification
gave a total yield of 97%.
The photoreaction of the dimethoxy-substituted N-methylphthalimide 79d with
3,4,5-trimethoxyphenyl acetate resulting in the formation of 89 illustrates another
pathway that PET can occur (Scheme 4.9).
CO2
H3CO
PETaryl
H3CO
OCH3
OCH3
H3CO
H3COCO2
H3CO
H3CO
OCH3
- CO2
+
NH3CO
H3CO
O
O
CH3 +
NH3CO
H3CO
O
O
CH3 +
2. C-C
1. H+
NH3CO
H3COO
CH3
HO
H3COOCH3
OCH3
89
79d
Scheme 4.9 PET-activity of dimethoxy-substituted N-methylphthalimide
Since the highly fluorescent singlet state of this phthalimide is not quenched by
simple alkyl carboxylates, electron transfer from the carboxylate function will not
101
occur. The electron-rich 3,4,5-trimethoxyphenyl-group is known to function as an
electron donor in the photodecarboxylative addition. The oxidation strength of the
excited dimethoxylated phthalimide is thus lower than that of the excited phthalimide
analogue. Based on literature data and the successful addition of the α-thioalkyl
carboxylate, photoadditions to dimethoxy phthalimide do not take place for simple
carboxylates and require either a heteroatom with low oxidation potential or electron-
rich aryl groups in the α-position to the carboxylate.
This could explain the lower yield obtained in the reaction with the
dimethoxyphenylacetic acid. Even though it differs in only one methoxy group the
resulting difference in oxidation potential seems to be enough to hinder the electron
transfer from the aryl group.
The dehydration reactions of both 88 and 89 were carried out resulting in the
formation of 90 and 91 as shown in Scheme 4.10.
N
O
HO
CH3 N CH3
O
DCM
HCl
88 R = H89 R = OCH3
90 R = H91 R = OCH3
ROCH3
H3CO
H3CO
H3CO
R
H3CO OCH3
H3CO
H3CO
Scheme 4.10 Experiment 78 and 79.
In experiment 78 (88 → 90) both isomers of the desired product were formed in a
ratio of 74:26 while in experiment 79 (89 → 91), both isomers of the desired product
were formed in a ratio of 78:22, while the yields were 93% and 95% respectively as
shown in Table 4.3 below. In both cases the E-isomer was the major isomer formed.
102
Table 4.3 Results for experiments 78 and 79.
compound R yield [%] d.e. [%]
90 H 93 48 91 OCH3 95 56
4.3.3.1 Attempted electrocyclic ring closure
Both 90 and 91 were used in an attempted electrocyclic ring closure reaction in the
presence of DDQ (previously optimised procedure).
N
O
CH3
H3CO
H3CO
R
H3CO OCH3
H3CO
H3CO
H3COOCH3
N CH3
R
O
hν or darkBenzene (DDQ)
90 R = H91 R = OCH3
Scheme 4.11 Experiments 80-85.
All reactions were conducted in deuterated benzene, on a small scale in an NMR
tube. Reactants were irradiated for up to 35 hours with DDQ present; however there
was no evidence of either product in the respective 1H-NMR’s. Reference reactions
were irradiated without DDQ being present simultaneously and these again showed
no formation of product. Likewise, “dark reactions” were performed with DDQ
present to act as controls and these reactions all resulted in no product formation.
These results prove unequivocally that ring closure will not occur without the
necessary iodo group on the upper ring being present, even in the company of the
oxidant DDQ. Knowing this, further reactions with iodo acids were investigated.
103
4.3.4 Further reactions for the synthesis of iodo precursors
Dimethoxy-NMP, 79d was reacted with 81a and 81b, however these reactions were
not successful as no product was formed (Scheme 4.12). It was very difficult to
dissolve the starting materials in the usual solvent of acetone:water (1:1) and even
when heat was applied they did not stay in solution for the duration of the irradiation
period. In most cases, the starting material 79d precipitated out and was recovered.
N
O
Oacetone / water
+N
O
OHCO2K
H3CO
OCH3
CH3
OCH3
RI
I
R OCH3
CH3
hνH3CO
H3COH3CO
H3CO79d 81a R = H
81b R = OCH3
Scheme 4.12 Experiments 86 and 87.
In experiment 86, 79d was reacted with 81a and following irradiation for a total of
32 hr 79d precipitated almost in its entirety. The crude 1H-NMR showed no sign of
the product being formed. In experiment 87, 79d was reacted with 81b and even after
irradiating for 53 hr the starting material was recovered. Following work-up, the
crude 1H-NMR consisted mainly of 81b and no evidence of the photoproduct was
present.
The reagent 79d has a reduction potential of EOx = -1.98 V versus
ferrocene/ferricenium, i.e. 100 mV more negative than that of the methoxyfree parent
compound 1 and as discussed previously needs an electron rich aryl group in order
for electron transfer to occur. Despite the low yield of product in the reaction of 79d
with the dimethoxyphenylacetic acid 87a, as 79d underwent reaction with both non-
iodinated reaction partners 87a,b, it is obvious that the iodo group is causing
additional issues
As both starting materials showed solubility issues, it was thought that a change in
solvent could solve this problem.
104
4.3.4.1 Solvent study
For this study 81b was the acid partner selected to react with 79d as shown in
Scheme 4.13. Several solvent systems were applied which are shown in Table 4.4.
Before conducting experiments with DMF as the solvent, a stability check was
performed on 79d by irradiating it in DMF overnight. The solvent was then removed,
the starting material recovered and the resulting 1H-NMR showed 79d to be
unchanged, therefore proving DMF was safe to use as a solvent.
N
O
Osolvent system
+N
O
OHCO2K
H3CO
OCH3
CH3
OCH3
H3COI
I
H3CO OCH3
CH3
hνH3CO
H3COH3CO
H3CO79d 81b
Scheme 4.13 Experiments 89-95.
Table 4.4 Solvent study with 79d and 81b.
experiment solvent system ratio 89 Acetone:Water 2:1 90 Acetone:Water 4:1 91 Acetone:Water 10:1 92 Acetone:DCM 1:1 93 a(Acetone:Water):DMF 4:1 94 a(Acetone:Water):DMF 1:1 95 Acetone:Ethanolic microemulsion 1:1
a (Acetone:Water) ratio is 1:1
For all these reactions, the cooling device (cold finger) was set up as usual but was
not activated when the Schlenk flasks containing the reaction solutions were placed
in the Rayonet reactor, as heat seemed to encourage the reactants to dissolve. In all
cases, the reactants were irradiated for a period of at least 24 hr and the starting
material 79d was found to be the observed precipitate.
In experiments 89-91, by increasing the volume of acetone used in the solvent
system of acetone:water, the reactants seemed to go into solution slightly more
105
readily, however during irradiation 79d continued to precipitate. The same occurred
in experiment 92 with 79d being recovered in a yield of 83%.
In experiments 93 and 94 using (acetone:water):DMF, despite the starting material
eventually precipitating it did stay in solution for a slightly longer period of time (3-4
hr) than in the absence of DMF. Finally in experiment 95, an ethanolic
microemulsion was used in conjunction with acetone, however it seemed to keep the
reactants in a suspension as opposed to dissolving them. To further encourage the
reaction to proceed, a more dilute solution of 79d and 81b was used in experiment
95. Unfortunately, the unreacted starting material 79d was again recovered.
The fact that no photoproducts were formed, despite the reagents eventually staying
in solution for a period of time while being irradiated, showed that solubility issues
experienced were not the sole reason for the reactions not going to completion. Also,
taking into account the fact that the reactions with 79d and the non-iodo acid partners
were successful it seems clear that the iodo function is the source of the issue.
Referring back to the “space filling” model for 81d shown earlier, the results of the
solvent study seem to strengthen this postulated explanation.
4.3.5 Reactions of phthalimide and dimethoxyphthalimide with iodo-
substituted phenylacetic acids
In experiment 96, phthalimide 7 was irradiated in the presence of potassium iodo-
phenylacetate for a period of 6 hr, as shown in Scheme 4.14, resulting in the
formation of 92 in a yield of 78%.
NH
O
Oacetone / pH 7 buffer
+NH
O
HOCO2K
Ihν
7
I
92 (78%)
Scheme 4.14 Experiment 96.
106
In experiments 97 and 98, phthalimide 7 was also irradiated in the presence of 81a
and 81b for a period of 23 hr in both cases (Scheme 4.15). Neither reaction was
successful, and in the case of experiment 97, 81a was recovered following
purification of the crude product.
NH
O
Oacetone / pH 7 buffer
+NH
O
HOCO2K
H3CO
OCH3
OCH3
RI
I
R OCH3
hν
7 81a R = H81b R = OCH3
Scheme 4.15 Experiments 97 and 98.
Dimethoxyphthalimide 79e was also reacted with all three iodo acids as shown in
Scheme 4.16. In these cases, as seen previously when using 79d as starting material,
solubility of 79e was also an issue so DMF or, in the case of experiment 101,
formamide were added. The use of these solvents, in conjunction with the original
(acetone / pH 7 buffer) solution, vastly improved the solubility of 79e. In all cases,
the desired product was not formed.
NH
O
Oacetone / pH 7 buffer(DMF or formamide)
+NH
O
HOCO2K
R2
R2
R3
R1I
I
R1 R3
hν
79e 93 R1 = R2 = R3 = H81a R1 = H, R2 = R3 = OCH381b R1 = R2 = R3 = OCH3
H3CO
H3COH3CO
H3CO
Scheme 4.16 Experiments 99-101.
107
The various solvent systems used are shown in Table 4.5. In experiments 99 and
100, the reagents stayed in solution for the entire irradiation period. Unfortunately,
this did not result in product formation. In experiment 101, the starting material 79e
was seen to precipitate and was also visible in the crude 1H-NMR.
Table 4.5 Solvent systems for experiments 99-101.
experiment iodo acid solvent system ratio time [hr]
99 93 a(Acetone:pH 7 buffer):formamide 7:3 21 100 81a a(Acetone:pH 7 buffer):DMF 7:3 21 101 81b a(Acetone:pH 7 buffer):DMF 3:1 45.5
a (Acetone:pH 7 buffer) ratio is 1:1
These results show that varying the starting material does little to improve the
addition reactions of the iodo acids. Despite the solubility issues of 79d and 79e,
which appear to be a separate problem, the main difficulty lies with the iodo acids
and the bulkiness of the iodo substitient causing steric hindrance which, in turn, is
preventing the reactions from progressing.
4.3.6 Attempted iodination of precursors
In a final attempt to sidestep the problems encountered previously, it was attempted
to iodinate the previously formed photoproduct by the same method used to
synthesise the iodo acids. This proved to be unsuccessful; the desired product was
not formed.
N
O
HO
OCH3H3CO OCH3
CH3
H3CO
H3CO
89
N
O
HO
OCH3H3CO OCH3
CH3
H3CO
H3CO
I
I2, CF3CO2Ag
CHCl3
Scheme 4.17 Experiment 102.
108
The same procedure was attempted with the dehydrated photoproduct 91 and
regrettably, the outcome was the same.
N CH3
O91
H3CO
H3CO OCH3
H3CO
H3CO
I2, CF3CO2Ag
CHCl3N CH3
O
I
H3CO
H3CO OCH3
H3CO
H3CO
Scheme 4.18 Experiment 103.
109
4.4 Summary
A three-step procedure which involved an initial photoaddition reaction, dehydration
of the resulting photoproduct and eventual ring closure by irradiation in benzene,
produced the unsubstituted or parent aristolactam 82c, however substituent groups
such as alkoxy or hydroxy groups, are required for a range of biological activity.
After synthesising the starting materials, a number of photoaddition reactions were
attempted using NMP (1) and Dimethoxy-NMP (79d) with both iodo (81a,b) and
non-iodo di/tri-methoxyphenylacetic acids (87a,b). Overall, the reactions of 79d with
81a,b were not successful, while reactions of 1 with 81a,b were somewhat sluggish,
however did result in product formation.
The final ring closure step was attempted with both iodo (85) and non-iodo
dehydration products (90, 91) and it was proved that ring closure only occurred via
oxidative dehydrohalogentation as the attempted oxidative electrocyclisation was
unsuccessful.
The issues associated with the initial photoaddition reactions were investigated.
These were originally thought to be solubility problems, however following a solvent
study, it was thought that electronic issues were also causing problems, especially
with the reactions using 79e and 81a,b. Photoadditions were also attempted with
phthalimide and dimethoxyphthalimide however there was no improvement with
these reactions. Following the synthesis of the non-iodinated photoaddition product
(89) and the non-iodinated dehydrated photoaddition product (91), it was finally
attempted to iodinate both compounds by the same method used to synthesise the
starting materials 81a,b. This method was also revealed to be unsuccessful.
Nevertheless, the unsubstituted skeleton aristolactam and a trimethoxy-substituted
aristolactam were both synthesised successfully.
110
Chapter 5
111
5 Synthesis of phthalocyanines from photochemically
derived fluorinated phthalonitriles
5.1 Introduction
Phthalonitrile derivatives will be synthesised by photochemically reacting
tetrafluorophthalonitrile (TFPN) with three different methoxy substituted benzenes.
As water-solubility is a desired attribute in fluorescent compounds, meaning they can
be used in cell imaging studies, it will be attempted to water-solubilise the resulting
phthalonitrile derivatives by introducing water-soluble functional groups.
As phthalonitriles can be used as precursors to phthalocyanines (Pcs), it will be
attempted to condense the methoxy-substituted phthalonitrile derivatives to their
respective Pcs. The preparation of a water-soluble Pc will be attempted by
introducing a sulfonate moiety, which would allow for enhanced solubility in
alcohols and water making it a suitable sensitiser for PDT. If selective sulfonation
can be achieved this would result in an exciting new sulfonated phthalocyanine, the
like of which has not been seen before.
112
5.2 Synthesis of starting materials
5.2.1 Photochemical reactions
In experiments 104-106, shown in (Scheme 5.1) below, tetrafluorophthalonitrile 41
was irradiated with methoxy-substituted benzenes (2 equiv.) in a dilute concentration
of approximately 4 × 10-3 M. All three reactions were irradiated for a period of 3
days. Following work-up, the crude product was purified by column
chromatography. The results are shown in Table 5.1.142, 143
NCF
F
FF
NC
OCH3
+hν
DCM
FNC
NC
F F
OCH3
R1 R2
R1
R2
95a-c94a R1 = R2 = H94b R1 = OCH3, R2 = H94c R1 = R2 = OCH3
41
Scheme 5.1 Experiments 104-106.
Table 5.1 Results for experiments 104-106.
compound R1 R2 yield [%]
95a H H 42 95b OCH3 H 50 95c OCH3 OCH3 47
The reason for the moderate yields after such a long irradiation period may be due to
the fact that the product also absorbs light and so is in competition with the starting
material. The same reactions were carried out over a shorter irradiation period of 24
hr and showed little difference in isolated yields. Therefore even after irradiating for
prolonged periods of time, the improvements in the yields are minor.
113
OCH3OCH3
FNC
NC
F F
OCH3
OCH3
2.02.53.03.54.04.55.05.56.06.57.07.5 ppm
3.
80
33
.8
80
3.
91
3
6.
58
46
.5
90
6.
61
56
.6
21
6.
63
76
.6
42
7.
13
37
.1
54
3.33
3.24
0.35
1.02
1.04
1.00
Harom.
Hc Hb
Ha
Figure 5.1 1H-NMR of 95b in CDCl3.
From the 1H-NMR of 95b, shown in Figure 5.1, the peaks found at 3.80 ppm and
3.88 ppm represent the methoxy groups. The first of the three aromatic protons is
represented by the peak found at 6.59 ppm. This corresponds to Ha, found between
the two methoxy groups, and at first glance appears to be a singlet, however on
closer inspection slight splitting can be seen, which is caused by 4J coupling with its
nearest proton neighbour Hb. The peak found at 6.63 ppm represents Hb which is
split into a doublet by Hc, while also experiencing slight splitting (4J coupling) from
the previously mentioned Ha. The peak representing Hc is found at 7.14 ppm and, due
to 3J coupling with Hb, appears as a doublet with no further splitting as it is too far
away from the Ha for this to occur.
The 19F-NMR proves substituition at the 4-position as three peaks are seen
representing the remaining three fluorines, two of which appear as quartets and one
of which appears as a triplet.
114
FNC
NCF
F
FOCH3
OCH3
+
FNC
NC
F F
OCH3F
HOCH3
FNC
NC
F F
OCH3
OCH3
hν
- HF
41 94b
95b
Scheme 5.2 Proposed mechanism for the synthesis of 95b.
The proposed mechanism by Pratt et. al,142 as shown in Scheme 5.2, describes the
biaryl formation via a direct coupling route. Upon loss of HF from the intermediate,
the product 95b is formed. The selective coupling at the 3 or 4 position as opposed to
the 2 and 5 position could be due to steric hindrance from the nitrile groups.
FNC
NC
F F
OCH3
R1
R2
95a R1 = R2 = H95b R1 =OCH3, R2 = H95c R1 = R2 = OCH3
0
0.2
0.4
0.6
0.8
1
1.2
1.4
290 310 330 350 370 390Wavelength (nm)
Abs
62c62b62a
95c95b95a
Figure 5.2 UV-Vis spectra for photoproducts 95a-c.
115
The UV-Vis spectra obtained for 95a-c are shown in Figure 5.2. By comparing the
spectra we see that products 95b and 95c have similar maximum absorptions of λmax
= 334 nm and λmax = 336 nm respectively. The mono-substituted methoxy
photoproduct 95a shows absorption at λmax = 327 nm.
5.3 Sulfonation of phthalonitrile derivatives
5.3.1 Synthesis of sulfonated products
Initially, it was attempted to convert the nitrile groups of the phthalonitrile
derivatives into the corresponding amides. According to a method reported by
Moorthy et al,.144 95b was stirred in TFA:H2SO4 (4:1) at R.T for 2 days. This did not
produce the expected product shown in Scheme 5.3, instead selective sulfonation
was found to have taken place (Scheme 5.4).
F
F F
OCH3
OCH3TFA:H2SO4 (4:1)
FNC
NC
F F
OCH3
OCH3
95b
NH2NH2
O
O
Scheme 5.3 Attempted conversion of nitriles to amides using 95b as a substrate.
In experiment 107 compound 95b was stirred in TFA:H2SO4 (4:1) at R.T for 2 days.
Following work-up, the crude product was purified by recrystallisation and the yield
of 96b was found to be 88%.
116
FNC
NC
F F
OCH3
OCH3
SO3H
TFA:H2SO4 (4:1 / 1:1)
FNC
NC
F F
OCH3
OCH3
95b 96b
(H2SO4)
Scheme 5.4 Experiments 107-109.
Table 5.2 Varying solvent for sulfonation of 95b.
experiment solvent time [days]
yield [%]
107 TFA:H2SO4 4:1 2 87 108 H2SO4 2 38 109 TFA:H2SO4 1:1 4 29
To optimise the conditions, 95b was dissolved in H2SO4 at R.T. and allowed to stir
for 2 days. The sulfonated product was isolated although a lower yield of 38% was
obtained. In experiment 109, 95b was stirred at R.T in TFA:H2SO4 (1:1) for a total of
4 days. The yield was found to be 29%.
117
2.02.53.03.54.04.55.05.56.06.57.07.58.0 ppm
3.
98
84
.0
68
7.
02
5
7.
84
1
3.00
3.03
1.00
0.98
OCH3OCH3
Harom.
FNC
NC
F F
OCH3
OCH3
SO3H
Figure 5.3 1H-NMR of 96b in C2D6CO.
From the 1H-NMR of 96b, shown in Figure 5.3 above, we can see that the
photoproduct 95b was selectively sulfonated in only one position. As the two
remaining aromatic protons are represented by singlets at 7.03 ppm and 7.84 ppm,
the ortho-position shown is the only possible position that could be sulfonated as the
peaks would show slight splitting if sulfonation occurred at the meta-position. The
fact that the electron-donating methoxy groups are para- and ortho-directing would
further support this structure. Sulfonation does not occur at the ortho-position
between the two methoxy groups presumably due to steric hindrance.
This was confirmed by mass spectrometry, as [M + Na]+ peak was found at 421 m/z,
while in the negative mode the [M]- peak was found at 397 m/z. The calculated
molecular weight for 96b was 398 g/mol.
118
0
0.1
0.2
0.3
0.4
0.5
0.6
0.7
0.8
290 310 330 350 370 390
Wavelength (nm)
Abs 62b
63b95b96b
Figure 5.4 UV-Vis spectra of 95b and its corresponding sulfonated product 96b.
The product 96b was examined for potential use in cell imaging using the lung
adenocarcinoma cell line A549. The initial test used cells at the exponential growth
phase, these were treated with a number of concentrations of the compound for 24
hours and visualised using a leica SP2 AOBS confocal. The cells were excited with a
405nm laser and scanned for excitation from 420nm to 650nm.
In a repeat experiment the cells were treated with neat compound (8μg/ml) for 1 hour
and analysed with a flow cytometer exciting at 305nm. In both cases no fluorescence
was observed.
Investigative sulfonation procedures were also carried out with the mono-substituted
methoxy photoproduct 95a and the results are summarised in Table 5.3.
FNC
NC
F F
OCH3
SO3H
TFA:H2SO4 (4:1 / 1:1)
FNC
NC
F F
OCH3
95a 96a
Scheme 5.5 Experiments 110 and 111.
119
In experiment 110, 95a was stirred overnight in TFA:H2SO4 (4:1) at R.T and upon
quenching the reaction with water a precipitate was seen to form. This was isolated
and found to be the starting material 95a. From this, it was assumed the reaction was
unsuccessful, however, following work-up of the filtrate, the 1H-NMR of the crude
product showed it to contain the desired sulfonated product 96a with some starting
material also present. This was purified by recrystallisation and found to have a yield
of 26%.
Table 5.3 Summary of results for sulfonation of 95a.
experiment solvent time [days]
yield [%]a
110 TFA:H2SO4 4:1 1 26 111 TFA:H2SO4 1:1 4 73
a Yield of 96a.
In experiment 111, 95a was stirred in TFA:H2SO4 (1:1) at R.T for a total of 4 days.
Following work-up, the 1H-NMR showed this to be the desired product in a yield of
73% with no recrystallisation necessary.
Finally, the sulfonation procedure was applied to the trimethoxy-substituted
photoproduct 95c. The results are shown in Table 5.4.
FNC
NC
F F
OCH3
SO3H
TFA:H2SO4 (4:1 / 1:1)
FNC
NC
F F
OCH3
95c
OCH3
OCH3
OCH3
OCH3
96c
Scheme 5.6 Experiments 112 and 113.
120
Table 5.4 Results for attempted sulfonation of 95c.
experiment solvent time [days]
yield [%]a
112 TFA:H2SO4 4:1 1 0 113 TFA:H2SO4 1:1 4 0
a yield of 96c.
In experiment 112, 95c was stirred in TFA:H2SO4 (4:1) at R.T overnight and upon
quenching the reaction with water a precipitate was seen to form. This was isolated
and found to be the starting material 95c. Following work-up of the filtrate, the 1H-
NMR of the crude product confirmed it to be starting material. It was clear that
sulfonation did not occur, which was further confirmed when preparing the NMR
sample as the crude product dissolved in CDCl3.
In experiment 113, 95c was stirred in TFA:H2SO4 (1:1) at R.T for a total of 4 days.
Following work-up, even after the extended reaction period, the sulfonated product
was not formed. It is assumed sulfonation did not occur due to steric hindrance
caused by the presence of three methoxy groups on the aromatic ring.
121
5.4 Synthesis of phthalocyanines
5.4.1 Synthesis of phthalocyanines from phthalonitrile precursors
According to a method developed by Murphy143 the Pc 97b was formed in a melt of
95b with zinc acetate dihydrate. The reaction was performed on a carousel under N2.
After heating to 190oC for 1.5 hr the reaction mixture turned deep green in colour
and the reaction was complete. The yield of 97b was found to be 90%.
N
NN
N
N
N
NN
H3CO
OCH3
OCH3
OCH3
OCH3
OCH3
OCH3
H3CO
F F
F
F
F F
F F
F F
F FZn
97b (90%)
FNC
NC
F F
OCH3
95b
OCH3
Zinc acetate dihydrateΔ
Scheme 5.7 Experiment 114.
122
A UV-Vis absorption spectrum was obtained for this product and compared with the
UV-Vis spectrum of the phthalonitrile precursor 95b (Figure 5.5). The Pc product
showed a considerable shift at 693 ppm, which is red-shifted compared to
unsubstituted Pcs, confirming the presence of the desired Pc.
0
0.1
0.2
0.3
0.4
0.5
0.6
0.7
0.8
290 390 490 590 690Wavelength (nm)
Abs 64b
62b97b95b
Figure 5.5 UV-Vis spectra of 95b and 97b.
The previous procedure was also used to convert 95a into its corresponding Pc 97a
as shown in Scheme 5.8. The yield of 97a was found to be 67%.
123
N
NN
N
N
N
NN
OCH3
OCH3
OCH3
H3CO
F F
F
F
F F
F F
F F
F FZn
97a (67%)
FNC
NC
F F
OCH3
95aZinc acetate dihydrate
Δ
Scheme 5.8 Experiment 115.
A UV-Vis absorption spectrum was also obtained for this product and compared with
the UV-Vis spectrum of its phthalonitrile precursor 95a (Figure 5.6). The Pc product
showed a considerable shift at 693 ppm confirming the presence of the desired Pc.
124
0
0.1
0.2
0.3
0.4
0.5
0.6
0.7
0.8
290 390 490 590 690 790
Wavelength (nm)
Abs 64a
62a97a95a
Figure 5.6 UV-Vis spectra of Pc 97a and its precursor 95a.
The product 97a showed a peak at 694 ppm, once again confirming the presence of
the desired Pc. These Pcs were subsequently used in an attempted sulfonation in the
next section.
5.4.2 Synthesis of sulfonated phthalocyanines
First, it was attempted to synthesise a sulfonated Pc directly from the corresponding
sulfonated precursor using 96b as the starting material. This reaction was heated at
190oC for 2 hr and a deep green colour was seen indicating that a Pc had been
formed. However when the 1H-NMR was obtained, the sulfonated group seemed to
cleave as there were three aromatic proton peaks seen instead of the expected two
peaks for the sulfonated phthalocyanine. The reaction conditions may have been too
harsh to maintain the sulfonate group.
125
FNC
NC
F F
OCH3
96b
OCH3
Zinc acetate dihydrateΔ
N
NN
N
N
N
NN
H3CO
OCH3SO3H
OCH3
OCH3
SO3H
OCH3
OCH3
HO3S
OCH3
H3CO
HO3S
F F
F
F
F F
F F
F F
F FZn
98b
SO3H
Scheme 5.9 Experiment 116.
As preparing the sulfonated Pcs directly from the sulfonated precursors proved
unsuccessful, it was then attempted, in experiment 117, to sulfonate the previously
formed phthalocyanine 97b. Following work-up, this method appeared to be
successful as the 1H-NMR showed there to be only two aromatic proton peaks
present.
126
N
NN
N
N
N
NN
H3CO
OCH3SO3H
OCH3
OCH3
SO3H
OCH3
OCH3
HO3S
OCH3
H3CO
HO3S
F F
F
F
F F
F F
F F
F FZn
98b
N
NN
N
N
N
NN
H3CO
OCH3
OCH3
OCH3
OCH3
OCH3
OCH3
H3CO
F F
F
F
F F
F F
F F
F FZn
97bTFA:H2SO4 4:1
Scheme 5.10 Sulfonation of Pc 97b.
Selective sulfonation was therefore achieved as confirmed by 1H-NMR and the
desired Pc 98b obtained although was not in its pure state.
127
5.5 Summary
In this chapter, three methoxy-substituted (mono- 95a, di- 95b and tri- 95c)
phthalonitrile derivatives were synthesised. It was attempted to water-solubilise these
compounds by converting the nitrile groups to amides, using 95b as the test
substrate. The resulting product 96b, was indeed water soluble however; this was
achieved due to the addition of a sulfonate group and not the converted amide as
expected. The sulfonation occurred due to the use of the solvent mixture
TFA:H2SO4, and from 1H-NMR and MS data it was deduced that selective
sulfonation had taken place at the ortho-position.
Several optimisation reactions were performed for the sulfonation procedure with
95b before the procedure was applied to 95a and 95c. The sulfonation procedure was
found to be successful only for 95a (→96a). The reason the sulfonation was not
successful for 95c was thought to be due to steric hindrance.
The mono- and di-methoxy-substituted phthalonitrile derivatives (95a and 95b) were
successfully condensed to their related Pcs (97a and 97b). In order to synthesise a
selectively sulfonated Pc, two pathways were explored. It was first attempted to
synthesise the sulfonated Pc directly from the sulfonated product 96b. This method
however, proved unsuccessful as the sulfonate group was removed during
condensation. Sulfonation of the Pc 97b was then attempted, using the same
procedure to prepare 96b. This method appeared to be effective judging by the 1H-
NMR and UV-Vis spectra however; the presence of the selectively sulfonated Pc 98b
has yet to be confirmed.
128
Chapter 6
129
6 Microphotochemistry performed with selected reactions
6.1 Introduction
There has been increased interest over the past few years in the application of
microphotochemistry as described in Chapter 1. However, there are still some doubts
as to whether it is an efficient practice for organic synthesis. It will be attempted to
demonstrate that microphotochemistry is a viable alternative to conventional
methods. This will be done by performing several reactions using a microreactor and
then comparing the results obtained with those achieved by a conventional method,
namely photoreactions performed in a Rayonet reactor.
Some of the reactions chosen for comparison have already been presented in
previous chapters, such as inter-molecular PDC additions, however some intra-
molecular cyclisation reactions will also be attempted, and the results compared with
those achieved by the conventional method. In this way, various types of
photochemical reactions will be attempted in a microreactor and if successful, will
demonstrate that the microreactor is an effective method for a wide range of
photochemical reactions.
130
6.2 Synthesis of starting materials
6.2.1 Synthesis of N-phthalimido carboxylic acid derivatives
For the intra-molecular cyclisation reactions, four N-phthalimido carboxylic acid
derivatives were prepared. The first of which were 99a and 99b, which were
synthesised according to Kidd and King145 by reacting phthalic anhydride with γ-
aminobutyric acid and L-glutamic acid respectively (Scheme 6.1) in DMF at 150 oC.
The products were obtained in excellent yields of 98% and 96% respectively (Table
6.1). The 1H-NMR spectrum of 99a shows a peak at 3.77 ppm that can be assigned to
the NCH2 group, while the peak for the NCH group of 99b was found at 4.71 ppm.
99a R = H99b R = CO2H
O
O
O
N
O
O
+ CO2HH2N
R
CO2H
R
Δ
DMF
Scheme 6.1 Experiment 118 and 119.
Table 6.1 Synthesis of N-phthalimido carboxylic acid derivatives.
compound R 1H-NMR
[ppm] yield [%]
99a H 3.77a 98 99b CO2H 4.71b 96
a NCH2 peak in CDCl3, b NCH peak in CDCl3.
Two bulkier N-phthalimido carboxylic acid derivatives were also prepared, using a
two step procedure (Scheme 6.2). The products 100b and 101b were made using 2-
phthalimido-benzoic acid, EDC, TEA and stirring in DCM at room temperature for
48 hr with L-alanine-benzyl ester p-toluenesulfonate salt and L-leucine-benzyl ester-
p-toluenesulfonate salt respectively. The intermediates were then hydrogenated
giving the desired products in overall yields of 52% and 34% respectively as shown
in Table 6.2.
131
N
O
O
EDC
TEA
NH2R
OO
H3C
SO
O OH
+
H2
5% Pd/C
100b R = CH3101b R = i-Bu
CO2H
N
O
ONHO
R
O
OH
N
O
ONHO
R
O
O
100a R = CH3101a R = i-Bu
Scheme 6.2 Experiments 120 and 121.
Table 6.2 Synthesis of 100b and 101b
compound R 1H-NMR [ppm]
CHasym overall yield
[%]
100b CH3 4.59 52 101b i-Bu 4.6 34
In both experiments, the methyl esters of the desired products were also formed
during work-up of the final step, due to the fact that methanol was used as the
solvent. The crude product had to be further purified to remove the unwanted methyl
ester and this, along with the initial two-step procedure contributed to the moderate
yields obtained.
During work-up in the final step it was discovered that at high temperatures the
methyl ester was formed more readily. For example, upon rotary evaporation of the
solvent at 50oC, 101b was obtained in a low overall yield of <10%. The reactions
were subsequently repeated and the solvent evaporated at the lower temperature of
30oC, which gave the product 101b in an overall yield of 34% shown in Table 6.2.
To further improve the yield of 100b ethyl acetate was used in place of methanol in
132
the final step (experiment 120b) and this eliminated the unwanted esterification side
reaction. The overall yield of pure 100a was 62%.
6.3 Microphotochemical reaction set-up
6.3.1 Experimental set-up
For the irradiation experiments a Luzchem UV panel was selected. The panel was
fitted with 5 LZC-UVB lamps (λ = 300±20 nm) and the microreactor – a dwell
device manufactured by Mikroglas Chemtech - placed underneath it (Figure 6.1).
The microreactor possesses two separate channels; the reaction channel is 500 μm in
depth, 2,000 μm in width and 1.15 m in length, while the second channel was used
for cooling during the reactions. The reaction chamber was enclosed with tinfoil
sheets to contain the UV light during irradiation.
Figure 6.1: Microreactor in irradiation chamber.
Prior to irradiation, the reactant solution was degassed with Argon/Nitrogen while
the microreactor was purged by pumping the mobile phase through it. An example of
the reactant solution (shown in pink) being pumped through the reaction channel is
shown in Figure 6.2 while the microreactor is kept cool during irradiation by
pumping cold water through the second channel.
133
Figure 6.2 Luzchem dwell device microreactor.
The complete reaction set-up is shown in Figure 6.3. It shows the pre-mixed reactant
solution being driven through the microreactor by the syringe pump (1), where it is
irradiated and subsequently collected on the other side in a round bottom flask (2).
The coolant is constantly flushed through the second channel by a piston pump (3),
while the Luzcehm light panel (4) is kept cool by placing a container of ice (5) on top
during irradiation. Overheating of the lamps was found to be a problem initially,
which was thought to be due to the makeshift tinfoil surrounding, however the ice
bath proved to be an inexpensive solution to the problem. The UV shield (6) is
placed around the opening for safety reasons.
Figure 6.3 Reaction set-up.
Reactant in
Coolant in
Coolant out
Reactant out
1
234
56
134
Another problem that was encountered occurred during the re-filling of the syringe.
Once the 10 ml of reactant solution had been pumped through the system, the syringe
pump and the light source had to be turned off simultaneously. When removing the
syringe it was necessary to unscrew it from the tubing, which caused air to enter the
system and the solution already in the tubing to move forward which in turn affected
the residence time. This problem was solved by attaching a valve between the tubing
and the syringe (7). The valve was closed before removing the syringe, causing the
solution to remain in place while re-filling the syringe with the required solvent.
Once the syringe was re-attached, the valve was opened before the syringe pump and
the light source were once again turned on in unison.
Figure 6.4 Valve (7) introduced to the system.
7
135
6.4 Comparison reactions
The following reactions were chosen as model reactions to investigate the
effectiveness of microreactors versus standard photoreactors.
6.4.1 Reactions of NMP with phenylacetic acid and 2-iodophenylacetic
acid
The first reaction chosen as an optimisation reaction was that of NMP (1) with
phenylacetic acid (Scheme 6.3). As shown in Table 6.3, the formation of the desired
product increased with slower flow rates. The flow rate is inversely proportional to
the residence time so, as the flow rate decreases, the residence time increases which
in turn gives the reactants more irradiation time.
N
O
O
CH3 acetone / water+
hνN
O
CH3
HO
CO2K
1 67a
Scheme 6.3 Experiments 122-126.
For 67a, at the lowest attempted flow rate of 0.04 ml/min, the 1H-NMR showed only
the presence of the pure product, a complete conversion of 1 had been achieved after
only 42 minutes. No purification of the product was needed. By comparison, in the
standard Rayonet set-up, column chromatography had to be performed on the crude
product. After 1 hour of irradiation 54% of pure product was obtained. After 42
minutes in the dwell device, a yield of 100% was achieved!
136
Table 6.3 Optimisation of flow rates for reactions of 1 with phenylacetic acid.
compositiona flow rate [ml/min]
residence time [min] product NMP
0.12 14 25 75 0.08 21 40 60 0.06 28 42 58 0.05 33.6 59 41 0.04 42 100 0
a determined by 1H-NMR integration.
The graph shown in Figure 6.5 illustrates the changing composition of 1 and the
resulting product (67a) with respect to residence time. As the quantity of 1 declines,
the amount of product duly increases until there is no more starting material
remaining to convert into the corresponding product, meaning the reaction is
effectively complete.
0
20
40
60
80
100
120
0 10 20 30 40 50
Residence time (min)
Com
posi
tion
ProductNMP
Figure 6.5 Graph representing the changing composition of NMP and product
during irradiation in experiments 122-126.
137
Following the success of the initial reaction, a second model reaction was chosen,
one that required a longer irradiation period, that of 1 with 2-iodophenylacetic acid
(Scheme 6.4).
N
O
O
CH3 acetone / water+
hνN
O
CH3
HO
CO2K
1 82a
I
I
Scheme 6.4 Experiments 127a-c and 128-130.
Table 6.4 Optimisation of flow rates for reactions of 1 with 2-iodophenylacetic
acid.
compositiona flow rate [ml/min]
residence time [min] product NMP
0.25 6.7 5 95 0.16 10.4 8 92 0.12 14 10 90 0.08 21 14 86 0.04 42 19 81 0.01 168 23 77
a determined by 1H-NMR integration.
In the case of 82a, at the longest residence time of 168 min, a composition of 23%
product to 77% starting material was calculated based on the 1H-NMR. While full
conversion was not achieved during this time, the results were still quite impressive
given that, in the Rayonet reactor, an irradiation period of 4 hr was required for a
yield of 51% to be achieved.
138
6.4.2 Reactions of NMP with selected phenylacetates
The merits of using the microreactor were further investigated by attempting various
reactions with phenylacetates in the microreactor that were previously carried out in
the Rayonet, and comparing the results as shown in Figure 6.5.
N
O
O
CH3 +
N
O
CH3
HOCO2K
R2 R1
R3 R1
R2
R3
hν
acetone / water
1
67b, e, g and h
Scheme 6.5 Experiments 131-134 (Rn groups shown in Table 6.5).
Table 6.5 Comparison of results achieved in Rayonet vs Microreactor.
yield [%] compound R1 R2 R3 time [hr]
rayoneta microreactor 67b H CH3 H 4 32 93 67e H F H 4 39 53 67 g H Cl Cl 3 53 93 67h Br H H 5 35 60b
a pure yields, b irradiation time 4 hr 40 min
It is apparent that the yields obtained in the microreactor were far superior in all
cases despite the irradiation periods being the same for both set-ups. Even in the case
of 45, when the irradiation period was shorter in the microreactor than in the Rayonet
reactor, due to limitations of the syringe pump, the result was still an improvement
on the conventional method. This indicates that the reaction proceeds more
efficiently in the microreactor, and this observation is strengthened by the fact that
usually no purification was required with microreactor products compared to the
Rayonet.
139
6.4.3 Reactions of phthalimide with selected phenylacetates
Two examples of reactions using phthalimide as the starting material were then
attempted in the microreactor and compared with the conventional results (Table
6.6). As in the conventional method, because phthalimide was the chosen starting
material, the solvent system used was acetone/pH 7 buffer to prevent deprotonation
of the resulting products, which is caused by the increasing pH during irradiation.
NH
O
O
+NH
O
HOCO2K
R
R
hν
acetone / pH 7 buffer
1
68a R = CH368b R = F
Scheme 6.6 Experiments 135 and 136.
Table 6.6 Comparison results obtained using phthalimide as starting material.
yield [%] compound R rayonet
[3 hr] microreactor
[2 hr] 68a CH3 92 97 68b F 85 100
These sample reactions performed in the microreactor both resulted in higher yields
of purer photoproducts even with shorter irradiation times. The conventional results
obtained were already impressive so it was assumed that the microreactor would
make little difference, however remarkably it did in fact improve on the efficiency of
both reactions.
140
6.4.4 Photodecarboxylative addition of N-protected amino acids to NMP
As seen in chapter 3, N-protected amino acids were successfully reacted with 1
(Scheme 6.7). A selection of these reactions were then scaled down and performed in
the microreactor. The results are shown in Table 6.7 below.
N
O
O
CH3
R1
O
R2
N
O
CH3
HOHN
acetone / waterNH
CO2K
R2
R1
O+
N-protectedamino acids
hνR3R3
1 78c, d, e, i and j
Scheme 6.7 Experiments 137-145 (Rn groups shown in Table 6.7 below).
Table 6.7 Results obtained from experiments 137-145.
flow rate residence time compositiona compound R1 R2 R3
[ml/min] [min] product NMP 0.04 42 4 96
78c CH3 i-Pr H 0.008 210 42 58 0.08 21 26 74
78d CH3 i-Bu H 0.04 42 18 82
78e CH3 s-Bu H 0.08 21 27 73 0.04 42 32 68
78i t-BuCO CH3 H 0.01 168 93 7 0.04 42 28 72
78j t-BuCO PhCH2 H 0.01 168 53 47
a determined from 1H-NMR spectra.
These reactions required longer residence times. However, in all cases, full
conversion of 1 was not achieved, even in instances where the irradiation period was
the same as in the conventional method such as in the case of 78c. When irradiated
for a period of 3.5 hr, the composition of product vs NMP was calculated to be
42:58. In the conventional set-up, after the same irradiation period, full conversion of
1 was achieved and the product obtained in a yield of 52%. In the case of 78i, which
was irradiated for a length of 2 hr 48 min, a more impressive result was seen with
almost full conversion achieved, although in comparison, the conventional reaction
141
was irradiated for a period of 2 hr resulting in full conversion and the product
attained in a yield of 65%.
As the dimensions of the Rayonet reactor and the microreactor differ enormously,
space-time yields (STYs), which depend on the reactor geometry, were calculated for
the reactions shown in Table 6.7 (in cases of multiple reactions performed the
reactions with longest irradiation periods were used for the calculations) and the
related comparison reactions performed in the Rayonet reactor (as shown in Chapter
3) using Equation 2.
STY = n/VR × t
n = amount of 1 converted
VR = reactor volume
t = irradiation time
Equation 2 Space-time yield equation.
142
A more direct comparison can be made between both reactors from these calculated
STY values. The results are shown in Figure 6.6 which depict higher STYs for the
microreactor than for the Rayonet reactor.
0
0.2
0.4
0.6
0.8
1
1.2
1.4
78c 78d 78e 78i 78jcompound
STY
[mm
ol L
-1 m
in-1
]MicroreactorRayonet reactor
Figure 6.6 STYs for reactions performed in a Rayonet reactor (experiments 42,
44, 46, 50, 52) and comparison reactions performed in a microreactor
(experiments 138, 140, 141, 143, 145).
This superiority can be explained by the larger surface to volume ratio of the dwell
device in combination with the better light penetration within the microreactor. Even
though the microreactor results, shown in Table 6.7, initially appear less efficient
than those obtained in the Rayonet reactor, (as shown in Chapter 3; Table 3.3), when
the dimensions of both reactors are taken into account the STYs unambiguously
show that the microreactor is far superior to the conventional Rayonet reactor.
143
6.4.5 Reaction of TFPN and trimethoxybenzene
Taking an isolated example from chapter 5, the reaction of TFPN (41) and
trimethoxybenzene (Scheme 6.8) was used to investigate whether the microreactor
could improve the production of 95c. As was found previously with this reaction, the
product also absorbs light and hence is in competition with the starting material. It
was investigated whether the favourable dimensions of the microreactor would
eliminate this competition and therefore result in higher yields of product. The
concentration of the reactant solutions were varied, as well as the residence times, in
an attempt to achieve a more satisfactory outcome. The results are shown in Table
6.8
NCF
F
FF
NC
OCH3
+hν
DCM
FNC
NC
F F
OCH3H3CO OCH3
OCH3
OCH3
95c41
Scheme 6.8 Experiments 146-149.
Table 6.8 Results obtained from experiments 146-149.
compositiona TFPN in 10 ml [mmol]
flow rate [ml/min]
residence time [hr]
productb TFPN 0.15 0.007 4 0 100 0.15 0.002 14 18 82 0.03 0.002 14 84 16 0.04 0.001 28 61 39
a calculated from the 19F-NMR, b 95c.
Taking the results from the conventional approach into account, the microreactor
does appear to increase the performance of the reaction. The concentration of 41
used in the conventional method corresponds to 0.04 mmol, and the reactant solution
was irradiated for a total of 70 hr. The composition of product:TFPN was calculated
on average to be 58:42 from the 19F-NMR. Comparing this with the result obtained at
a flow rate of 0.001 ml/min, using the same concentration of 41, it was found that the
144
composition ratios were very similar (61:39) even though this reaction was only
irradiated for 28 hr. It was initially thought that it would be possible to increase the
concentration of the reactants when irradiating in the microreactor, however it seems
that this is not the case. In experiment 146, 0.15 mmol of 41 is irradiated for 4 hr and
it was found that no reaction took place. Even when the same concentration was used
and irradiated for a longer period of time (14 hr) the composition was calculated to
be 18:82 with the latter being the product. When a lower concentration (0.03 mmol)
of 41 was used and irradiated for the same period of 14 hr, a remarkable
improvement in product formation was observed with the composition calculated to
be 84:16.
The more dilute the solution, the more the starting material can absorb the light it
needs to react and produce the desired product.
6.4.6 Intra-molecular cyclisation reactions
All the previous examples featured are examples of inter-molecular reactions. In this
section a few examples of intra-molecular photoreactions were also chosen to
investigate how well they would transfer to the microreactor platform.
The reactions shown in Scheme 6.9 are two examples of these intra-molecular
reactions which both result in the same final product being formed (101).
N
O
HO
N
O
O10299a
CO2Khν
acetone / waterhν
acetone / waterN
O
O
CO2K
CO2K
99b Scheme 6.9 Experiments 150-155.
Table 6.9 Results for experiments 150 and 151 performed in the Rayonet
reactor.
starting material time [hr] yield [%]
99a 5.5 82 99b 2 42
145
In experiments 150 and 151, both 99a and 99b were irradiated in the Rayonet
photoreactor and the reactions allowed to go to completion, which was 5.5 hr and 2
hr respectively, and yields of 82% and 42% were obtained (Table 6.9).
The comparison reactions, experiments 152 and 153 (Table 6.10), were carried out
in the microreactor at a flow rate of 0.08 ml/min giving a residence time of 21 min
for both reactions resulting in yields of 60% and 33% respectively. This result was
quite impressive when taking into account the difference in irradiation periods.
As a further comparison, the reactions were again performed using the conventional
method, this time only irradiating for 21 min. The corresponding yields for
experiments 154 and 155 were found to be 64% and 17% respectively (Table 6.10).
Similar results were achieved using 99a as a substrate, while the microreactor
produced the product 102 in a more generous yield when 99b was used as starting
material.
Table 6.10 Comparison of cyclisation reactions; conventional vs. micro.
yield [%] experiment starting
materialtime [min] rayonet microreactor
152 and 154 99a 21 64 60 153 and 155 99b 21 17 33
As mentioned previously, in experiment 150, after 5.5 hr irradiation of the substrate
99a, a high yield of 82% was obtained. However, for experiment 151 a moderate
yield of 42% was obtained upon irradiation of the substrate 99b for 2 hr. The
differences in yields obtained can be explained by exploring the mechanisms of these
reactions. The starting material 99a follows the usual photodecarboxylation pathway
to obtain the cylisation product 102. The reaction mechanism for 99b is shown in
Scheme 6.10.
146
N
O
O
CO2K
CO2KN
O
O
CO2K
CO2
N
O
O
CO2K
N
O
O
CO2K
K
N
O
O
CO2K
K
- α-CO2
BET
- KOH
N
O
HO
γ-CO2
N
O
O
CO2
K
- γ-CO2
N
O
O
K
C-CN
O
O
- KOH
+ H2O
+ H2O
PET
α-CO2
PET
K
Scheme 6.10 Mechanism for the cyclisation reaction of 99b.
In the case of 99b, there are two carboxylates present so it would follow that a longer
irradiation time would be needed for this reaction to go to completion. The poor yield
can be put down to the fact that the reaction is incomplete, as there are two
photochemical reactions taking place here. 99b undergoes one photodecarboxylation
at the α-carboxyl, effectively resulting in the formation of 99a. This in turn
undergoes a second photodecarboxylation at the γ-carboxyl, which leads to the
eventual cyclised product.
Two further examples of intra-molecular reactions are shown in Scheme 6.11 using
the previously synthesised N-phthalimido carboxylic acid derivatives 100b and 101b.
In experiments 156 and 157, both starting materials were irradiated under
conventional conditions for a period of 4 hr and 2.5 hr resulting in yields of 40% and
58% respectively as shown in Table 6.11.
147
N
O
O
NH
OHO
O
N
O
O
NH
OHO
ON
O
HN
O
HO
R
100b 101b103, 104
hν
acetone / water
hν
acetone / water
Scheme 6.11 Experiment 156-159.
Table 6.11 Results obtained in experiments 156 and 157 using the conventional
method.
compound R time [hr] yield [%]
103 CH3 4 40 104 i-Bu 2.5 58
In experiments 158 and 159, the same reactions were performed in the microreactor
and once again showed more impressive yields than their conventional counterparts
with shorter irradiation times (Table 6.12).
Table 6.12 Results obtained in experiments 158 and 159 using the microreactor.
compound R flow rate [ml/min]
residence time [min]
yield [%]
103 CH3 0.01 168 35 104 i-Bu 0.03 56 87
In experiment 158, the product was formed in a yield of 35% after only 2 hr 48 min
while the conventional procedure achieved a yield of 40% after a total of 4 hr
irradiation. In particular, the result obtained in experiment 159 shows a marked
improvement in the efficiency of the reaction with an impressive yield of 87% being
achieved after an irradiation period of just 56 min, while the conventional method
only achieved a yield of 58% after a longer irradiation period of 2 hr 30 min.
148
One of the main differences between the two methods was that 16 lamps were used
to irradiate the solution in the Rayonet reactor, whereas only 5 lamps were used to
irradiate the microreactor under the Luzchem panel. If this is taken into account, all
the results obtained in the microreactor are even more impressive.
149
6.5 Summary
Several model reactions were chosen to perform in a microreactor, including inter-
molecular decarboxylative additions and intra-molecular cyclisation reactions, in an
attempt to reproduce or improve the results already obtained by the conventional
method. In most cases, the use of a microreactor enabled the decrease of reaction
times while also increasing yields. The reaction of NMP with phenylacetic acid was
chosen to optimise the reaction conditions in the microreactor as it was known to
have a short irradiation time (1-2 hr). It was found that as the flow rate decreased,
conversion rates increased until full conversion was achieved after 42 min, which
was achieved at a flow rate of 0.04 ml/min. A selection of further reactions including
NMP with N-protected amino aicds, phthalimide with phenylacetates and several
cyclisation reactions were also performed. In general all the results obtained were
superior to those acquired by the conventional method.
Comparison reactions were carried out in the conventional Rayonet chamber reactor,
under similar conditions. Space-time yields (STYs) were calculated for both reactors
to give a reasonable comparison. It is apparent from STYs that the microreactor is in
fact more efficient than the Rayonet reactor.
150
Thesis conclusions
One of the main aims of this work was to investigate the feasibility of microreactors
in organic synthesis. As a reference for this, a number of inter- and intra-molecular
photodecarboxylative (PDC) additions of carboxylates to phthalimides were first
performed in a conventional Rayonet reactor.
Phthalimide chemistry:
Phthalimide chemistry was extensively discussed in Chapters 2 and 3. A number of
compounds were successfully synthesised and several of these reactions were used as
model reactions to display the advantages of microreactors. The reaction of 1 with
phenylacetic acid was used to successfully optimise the microreactor set-up, and it
was also the first reaction to show the superiority of the microreactor compared to
the conventional method as demonstrated in Chapter 6. A number of comparison
addition reactions, using both 1 and 7 with various phenyl acetates, also exhibited
better results when performed in the microreactor.
Several reactions of 1 with N-acetylated amino acids resulted in incomplete
conversions of 1 to the target compounds, even when irradiated for the same
irradiation periods as in the conventional reactor. However, upon applying STY
calculations to both sets of results, which take reactor geometry into account, the
microreactor once again came out on top.
Aristolactam synthesis:
In Chapter 4, it was investigated whether aristolactams could be synthesised from the
PDC addition products via an efficient photochemical method. Two aristolactams
were successfully synthesised by this method, however there were limitations using
this approach which were investigated at length. It was thought that solubility
problems in addition to electronic effects were the cause of the issues encountered. It
was also proved that the final ring closure step occurs via dehydrohalogenation and
will not occur via electrocyclisation.
151
Phthalonitriles and phthalocyanines:
In Chapter 5, synthetic organic photochemistry was used for the preparation of three
phthalonitrile derivatives. Two of these derivatives were successfully selectively
sulfonated making them water soluble and thus, suitable compounds for labelling in
cell-imaging studies. As water solubility is also a desirable feature of Pcs, it was then
attempted to condense the dimethoxy-substituted phthalonitrile derivative to its
corresponding phthalonitrile. This method was not successful, however the
selectively sulfonated Pc 98b was thought to be synthesised by performing the
sulfonation after the Pc was formed. This valuable achievement has yet to be
confirmed, however the work shown in this chapter is certainly an exciting first step
in the process of selectively sulfonating a Pc.
The reaction to synthesise the trimethoxy-substituted phthalonitrile derivative was
also carried out in the microreactor at various flow rates and concentrations. These
reactions also showed an improvement in the conversion of 41 to the target
compound 95c, compared with the results obtained in the Rayonet reactor.
Investigating the feasibility of microreactors in organic photochemistry:
As mentioned in the thesis proposal the ultimate aim of this work was to prove that
microphotochemistry is an efficient tool in organic synthesis. By comparing the array
of results obtained by the conventional method with those achieved in the
microreactor, it was plain to see that the microreactor is a more efficient method of
performing reactions. In all cases, the microreactor gave superior results and when it
is taken into account that there were 16 lamps in the Rayonet reactor and only 5
lamps in the microreactor set-up, the results are even more impressive. The STY
calculations showed the effectiveness of the microreactor was down to its larger
surface to volume ratio combined with better light penetration. The fact that the
product is removed from the microreactor immediately after being formed is another
reason for the improved performance of the microreactor, as this allows the starting
materials to absorb the light more efficiently.
In general, the products formed in the microreactor also appeared cleaner which
meant that less purification was required, which is another advantage of the
microreactor. The only disadvantage with using this method instead of the
conventional one is the small amount of product obtained following a lengthy
experiment as, for example, at a flow rate of 0.08 ml/min only 1.68 ml of reactant
152
solution is irradiated during the 21 minute residence time. Consequently, to obtain a
sufficient amount of product for analysis becomes quite time-consuming. The
solution to this however, if necessary, is to run several microreactors in parallel so a
larger amount of product can be synthesised in the same period of time.
Thus far, the investigation into the use of microreactors has been very positive with
some remarkable results achieved. Of course there is room for improvement, which
could be achieved with new types of microreactors. For example a microreactor
could be constructed using a single lamp inserted into a cylindrical glass tube, with
clear tubing wrapped around the tube. The reactant solution could be pumped
through the tubing, which, depending on the length of tubing, could result in longer
residence times for a larger volume of solution. This system would also use less
energy due to the single lamp needed, making it a cheaper and more efficient reactor
than those commercially available.
From the reactions shown and discussed in this work it has been verified that
microreactors are an efficient tool in organic synthesis and that microphotochemistry
is a viable alternative to conventional methods.
153
Chapter 7
154
7 Experimental
Spectroscopic methods
NMR: NMR spectra were recorded on a Bruker 400 UltrashieldTM instrument
(400 MHz for 1H; 100 MHz for 13C) using the Bruker Topspin 2.0
software. Chemical shift values are referred to solvent residual
resonances: CDCl3 (7.26/77.36 ppm), DMSO-d6 (2.54/40.45 ppm) and
acetone-d6 (2.09/30.60 and 206.3 ppm). Chemical shifts δ are given in
ppm, coupling constants J in Hz.
UV-Visible spectroscopy: UV-Vis spectra were recorded using a Varian Cary 50
scan UV-Vis spectrophotometer.
Mass spectrometry: Mass spectra (MS) were recorded using a Bruker Daltonics
Esquire-LC ion trap MS with an electrospray ionisation interface at
atmospheric pressure. 100μl of each sample contained in a glass syringe
fitted to an automatic syringe pump was injected into the mass spec
detector at a rate of 300μl/h.
Chromatography methods
Column chromatography: Column chromatography was carried out using Merck
silica gel 60 (particle size 0.063-0.200 nm for column chromatography)
70-230 mesh ASTM.
Thin Layer Chromatography (TLC): Analytical thin-layer chromatography was
performed on aluminium sheets coated with 0.20 mm of Fluka silica gel
ITCL-cards with fluorescent indicator 254 nm, layer thickness: 0.2mm.
Conventional photolysis
Glassware: All photoreactions were performed in Pyrex® tubes of various volumes.
155
Conventional reactor: Photochemical reactions were performed in a RPR–200
Rayonet photochemical chamber reactor (Southern New England
Ultraviolet Company) equipped with RPR 3000 Ǻ lamps (λmax = 300 ±
25 nm). All reactions were carried out under an atmosphere of nitrogen.
Micro photolysis
Microreactor: Microreactions were performed in a dwell-device (Mikroglas), made
of FOTURAN® glass; total path length of 1.15 m (20 turns) on a 118
mm x 73 mm aperture and consisting of a (bottom) serpentine channel
with a second (top), heat-exchanging channel through which cooling
water is passed.
Irradiation source: The dwell-device was placed under a Luzchem UV-panel
equipped with 5 LZC-UVB lamps (300 ±25 nm).
Pump: A Harvard apparatus 11 plus syringe pump was used to pump the
degassed reactant solution through the dwell-device.
Solvents and reagents
All solvents and starting materials were obtained from commercial suppliers (Sigma-
Aldrich and Fluka) and were used without purification.
156
7.1 Chapter 2: Photoaddition reactions of NMP and phthalimide
Experiment 1
2-methylisoindoline-1,3-dione (NMP) (1) (SG-3)
N
O
O
CH3
C9H7NO2Mol. Wt.: 161.16 g/mol
N-Methylformamide (80 ml) and phthalic anhydride (10.0 g, 67.52 mmol) were
stirred and heated for 8 hr at 150oC. After cooling down to R.T. fine, colourless,
needle-like crystals were formed. The mixture was filtered by vacuum filtration,
washed with ~10 ml EtOH and then left to dry. This reaction mixture gave 6.5 g
(40.40 mmol; 60%) of N-methylphthalimide. It was observed that crystals also
formed in the filtrate when cooled on ice. These were also vacuum-filtered and
washed with ethanol. After drying, the yield of these crystals was found to be 1.3 g
(7.75 mmol; 11.5%). 1H-NMR spectra were obtained for both sets of crystals and as
both were found to be very pure, no further purification steps were necessary. The
product consisted of fine, colourless, needle-like crystals. The overall yield was 71%.
1H–NMR: (400 MHz, CDCl3): δ (ppm) = 3.11 (s; 3H; NCH3), 7.70 (dd; 3J = 8.6, 4J
= 5.6 Hz; 2H; CHarom), 7.84 (dd; 3J = 8.6, 4J = 5.6 Hz; 2H; CHarom). 13C–NMR: (100 MHz, CDCl3): δ (ppm) = 24.3 (1C; NCH3), 123.5 (2C; CHarom),
132.5 (2C; Cq), 134.2 (2C; CHarom), 168.8 (2C; C=O).
Literature reference No.: [123]
CAS No.: 550-44-7
157
7.1.1 General Procedure (A):
NMP (1.5 mmol) was dissolved in 10 ml of acetone. The addition partner (4.5 mmol)
was added to K2CO3 (2.25 mmol) and dissolved in 15 ml of distilled H2O and 5 ml of
acetone. These solutions were mixed together and poured into a 100 ml Pyrex
Schlenk flask and sonicated for 5 min. The Schlenk flask containing the solution was
placed in the photoreactor and 70 ml of a mixture of acetone/water (50:50) added.
The photoreactor was then switched on and the solution irradiated with light (λ =
300±20 nm) while purging with a slow stream of N2. The progress of the reaction
was checked periodically by TLC, using solvent mixture ethyl acetate:hexane (1:1).
When the reaction was complete (starting material spot had disappeared and product
spot had formed), acetone was removed by rotary evaporation at ~50oC and the
remaining solution was extracted with DCM (3 × 50 ml). The two layers were
separated (organic → bottom layer, aqueous → top layer) and the organic layer
washed with saturated NaHCO3 (2 × 30 ml) and then with saturated NaCl (2 × 30
ml). The organic layer was collected and dried over MgSO4, filtered by gravity
filtration and the DCM evaporated from the filtrate by rotary evaporation at ~40oC.
A 1H-NMR was obtained for the crude product. Column chromatography was then
carried out using solvent mixture ethyl acetate:hexane (1:1) and the fraction
containing the desired product collected. A 1H-NMR was subsequently obtained to
confirm this.
Experiment 2
3-hydroxy-3-isopropyl-2-methylisoindolin-1-one (66a) (SG-154b)
N
O
HO
CH3
C12H15NO2Mol. Wt.: 205.25 g/mol
General procedure (A) was followed using NMP (0.2 g, 1.51 mmol), i-butyric acid
(0.4 g, 4.56 mmol) and K2CO3 (0.3 g, 2.26 mmol). A bubbler filled with a solution of
saturated barium hydroxide was placed on one arm of the Schlenk flask to test for the
158
presence of CO2. This test was positive (solution turned from clear to milky) so CO2
was indeed formed during the reaction. After 7 hr the TLC showed the product was
formed. The solution was clear and yellow at this point. The product was found to be
a colourless solid and the 1H-NMR obtained confirmed this was the pure product.
The yield was found to be 0.2 g (1.11 mmol, 74%). The product was a yellow solid.
1H–NMR: (400 MHz, C2D6CO): δ (ppm) = 0.51 (d; 3J = 6.8Hz; 3H; CH3), 1.21 (d; 3J = 6.8Hz; 3H; CH3), 2.43 (m; 1H; CH), 2.91 (s; 3H; NCH3), 5.20 (br.s; 1H; OH),
7.50 (ddd; 3J = 7.2Hz; 4J = 1.2Hz; 1H; CHarom), 7.58 (ddd; 3J = 7.2Hz; 4J = 1.2Hz;
1H; CHarom), 7.61-7.66 (br.m; 2H; CHarom). 13C–NMR: (100 MHz, C2D6CO): δ (ppm) = 16.8 (1C; CH3), 17.5 (1C; CH3), 23.6
(1C; NCH3), 34.6 (1C; CH), 93.2 (1C; COH), 123.1 (1C; CHarom), 124.1 (1C;
CHarom), 129.8 (1C; CHarom), 132.1 (1C; CHarom), 133.6 (1C; Cq), 146.7 (1C; Cq),
167.0 (1C; C=O).
Literature reference No.: [34b]
CAS No.: 32360-86-4
Experiment 3
3-Allyl-3-hydroxy-2-methylisoindolin-1-one (66b) (SG-22)
N
O
CH3
HO
C12H13NO2Mol. Wt.: 203.24 g/mol
General procedure (A) was followed using NMP (0.2 g, 1.53 mmol), vinyl acetic
acid (0.38 ml, 4.50 mmol) and K2CO3 (0.3 g, 2.27 mmol). After 5 hr the TLC
showed a product was formed. The solution changed from colourless to pale yellow.
The crude yield was found to be 0.1 g. Following column chromatography it was
assumed from the TLC that the desired product was collected in fraction 2, which
159
was confirmed by 1H-NMR. The yield of the pure product was 0.1 g (0.36 mmol,
24%), which was bright yellow in colour.
1H–NMR: (400 MHz, CDCl3): δ (ppm) = 2.72 (dd; 2J = 14.0Hz; 3J = 7.6Hz; 1H;
CH2), 2.74 (s; 3H; NCH3), 2.89 (dd; 2J = 14.4Hz; 3J = 6.0Hz; 1H; CH2), 4.01 (br.s;
1H; OH), 4.89 (dd; 2J = 10.0Hz; 3J = 0.8Hz; 1H; CH2 olef), 4.96 (dd; 2J = 16.8Hz; 3J =
1.2Hz; 1H; CH2 olef), 5.09-5.19 (m; 1H; CHolef) 7.37 (m; 1H; CHarom) 7.48 (d; 3J =
7.2Hz; 1H; CHarom), 7.55 (m; 2H; CHarom). 13C–NMR: (100 MHz, CDCl3): δ (ppm) = 23.4 (1C; NCH3), 40.3 (1C; CH2), 90.0
(1C; C-OH), 119.6 (1C; CH2olef), 122.1 (1C; CHolef), 123.0 (1C; CHarom), 129.5 (1C;
CHarom), 130.6 (1C; CHarom), 131.1 (1C; Cq), 132.1 (1C; CHarom), 146.3 (1C; Cq),
167.3 (1C; C=O).
Literature reference No.: [146]
CAS No.: 3103-20-6
Experiment 4
3-Benzyl-3-hydroxy-2-methylisoindolin-1-one (67a) (SG-1)
N
O
CH3
HO
C16H15NO2Mol. Wt.: 253.30 g/mol
General procedure (A) was followed using NMP (0.2 g, 1.49 mmol), 2-phenylacetic
acid (0.6 g, 4.58 mmol) and K2CO3 (0.3 g, 2.25 mmol). After 1 hr the TLC showed
the product was formed. The solution was clear and a very light yellow in colour.
The crude material was found to be 0.5 g. Following column chromatography it was
assumed from the TLC, that the desired product was collected in the second fraction.
The 1H-NMR obtained confirmed this and the yield was found to be 0.2 g (0.80
mmol, 54%). The product was colourless and powder-like.
160
1H–NMR: (400 MHz, CDCl3): δ (ppm) = 2.88 (s; 3H; NCH3), 3.09 (d; 2J = 14.0Hz;
1H; CH2), 3.46 (d; 2J = 14.0Hz; 1H; CH2), 3.67 (br.s; 1H; OH), 6.86 (m; 2H;
CHarom), 7.10 (br.m; 3H; CHarom), 7.25 (d; 3J = 7.6Hz; 1H; CHarom), 7.32 (ddd; 3J =
7.2Hz; 4J = 0.8Hz; 1H; CHarom), 7.41 (d; 3J = 7.6Hz; 1H; CHarom), 7.45 (ddd; 3J =
7.6Hz; 4J = 1.2Hz; 1H; CHarom). 13C–NMR: (100 MHz, CDCl3): δ (ppm) = 23.9 (1C; NCH3), 42.4 (1C; CH2), 90.7
(1C; COH), 122.7 (1C; CHarom), 123.0 (1C; CHarom), 127.0 (1C; CHarom), 128.0 (2C;
CHarom), 129.5 (1C; CHarom), 130.0 (2C; CHarom), 131.1 (1C; Cq), 131.7 (1C; CHarom),
134.4 (1C; Cq), 146.1 (1C; Cq), 167.1 (C; C=O).
Literature reference No.: [18]
CAS No.: 4770-23-4
Experiment 5
3-(2-iodobenzyl)-3-hydroxy-2-methylisoindolin-1-one (67b) (SG-40)
N
O
CH3
HO CH3
C17H17NO2Mol. Wt.: 267.32 g/mol
General procedure (A) was followed using NMP (0.2 g, 1.51 mmol), p-tolylacetic
acid (0.7 g, 4.51 mmol) and K2CO3 (0.3 g, 2.25 mmol). After 2 hr the TLC showed a
product was formed. The solution was cloudy and a very pale yellow in colour. The
crude yield was found to be 0.4 g. The crude product was washed by adding a small
amount of acetone to the round bottom flask, swirling and removing the solvent. This
was repeated several times and the product seen to be a colourless powder which was
confirmed to be the pure product by 1H-NMR. The yield of the pure product was 0.2
g (0.80 mmol, 53%).
1H–NMR: (400 MHz, C2D6CO): δ (ppm) = 2.19 (s; 3H; CH3), 3.08 (s; 3H; NCH3),
3.32 (d; 2J = 13.6Hz; 1H; CH2), 3.50 (d; 2J = 14.0Hz; 1H; CH2), 5.38 (br.s; 1H; OH),
161
6.82 (dd; 3J = 8.0Hz; 2H; CHarom), 6.90 (dd; 3J = 8.0Hz; 2H; CHarom), 7.42-7.50
(br.m; 2H; CHarom), 7.60 (m; 2H; CHarom). 13C–NMR: (100 MHz, C2D6CO): δ (ppm) = 20.8 (1C; CH3), 23.9 (1C; NCH3), 42.4
(1C; CH2), 90.9 (1C; COH), 122.6 (1C; CHarom), 123.5 (1C; CHarom), 128.8 (2C;
CHarom), 129.4 (1C; CHarom), 130.4 (2C; CHarom), 131.8 (1C; CHarom), 132.8 (1C; Cq),
133.0 (1C; Cq), 136.2 (1C; Cq), 148.1 (1C; Cq), 166.6 (1C; C=O).
CAS No.: 1197385-24-2
Experiment 6
3-(4-hydroxybenzyl)-3-hydroxy-2-methylisoindolin-1-one (67c) (SG-43)
N
O
CH3
HO OH
C16H15NO3Mol. Wt.: 269.3 g/mol
General procedure (A) was followed using NMP (0.2 g, 1.52 mmol), 4-
hydroxyphenylacetic acid (0.7 g, 4.50 mmol) and K2CO3 (0.3 g, 2.26 mmol). After 5
hr the reaction was worked up and the crude material found to have a yield of 0.20 g.
The 1H-NMR obtained showed the product had been formed, but NMP was also
present. The ratio of NMP to product was calculated from the 1H-NMR to be 79:21.
Following column chromatography it was assumed from the TLC, that the desired
product was collected in fraction 8. The 1H-NMR obtained confirmed this and the
yield was found to be 0.07 g (0.27 mmol, 18%). The product was a colourless
powder.
1H–NMR: (400 MHz, C2D6CO): δ (ppm) = 3.08 (s; 3H; NCH3), 3.25 (d; 2J =
14.0Hz; 1H; CH2), 3.43 (d; 2J = 14.0Hz; 1H; CH2), 5.35 (br.s; 1H; OH), 6.56 (d; 3J =
6.4Hz; 2H; CHarom), 6.76 (d; 3J = 6.4Hz; 2H; CHarom), 7.43-7.50 (br.m; 2H; CHarom),
7.58 (m; 2H; CHarom), 8.15 (br.s; 1H; OH). 13C–NMR: (100 MHz, C2D6CO): δ (ppm) = 23.9 (1C; NCH3), 42.2 (1C; CH2), 91.1
(1C; COH), 115.3 (2C; CHarom), 122.6 (1C; CHarom), 123.6 (1C; CHarom), 126.2 (1C;
162
CHarom), 129.4 (1C; CHarom), 131.4 (2C; CHarom), 131.8 (1C; Cq), 133.0 (1C; Cq),
148.3 (1C; Cq), 157.0 (1C; Cq), 166.7 (1C; C=O).
Mass spec: [MS + Na]: 292 m/z; expected 269 m/z
Melting point: 147-150oC
CAS No.: 1197385-25-3
Experiment 7
3-(4-methoxybenzyl)-3-hydroxy-2-methylisoindolin-1-one (67d) (SG-47)
N
O
CH3
HO OCH3
C17H17NO3Mol. Wt.: 283.32 g/mol
General procedure (A) was followed using NMP (0.2 g, 1.53 mmol), 2-(4-
methoxyphenyl)acetic acid (0.8 g, 4.53 mmol) and K2CO3 (0.3 g, 2.28 mmol). After
4 hr the TLC showed the product was formed. The solution was cloudy and milky at
this point. The crude material was found to be 0.5 g. Following column
chromatography it was assumed from the TLC, that the desired product was collected
in fraction 8. The 1H-NMR obtained confirmed this and the yield was found to be 0.3
g (1.20 mmol, 78%). The product was a yellow, oily solid.
1H–NMR: (400 MHz, C2D6CO): δ (ppm) = 3.08 (s; 3H; NCH3), 3.29 (d; 2J =
14.0Hz; 1H; CH2), 3.47 (d; 2J = 13.6Hz; 1H; CH2), 3.69 (s; 3H; OCH3), 5.40 (br.s;
1H; OH), 6.65 (d; 3J = 8.8Hz; 2H; CHarom), 6.86 (d; 3J = 8.8Hz; 2H; CHarom), 7.42-
7.50 (br.m; 2H; CHarom), 7.59 (m; 2H; CHarom). 13C–NMR: (100 MHz, C2D6CO): δ (ppm) = 23.7 (1C; NCH3), 42.1 (1C; CH), 55.2
(1C; OMe), 91.3 (1C; COH), 113.8 (2C; CHarom), 122.9 (1C; CHarom), 123.7 (1C;
CHarom), 128.0 (1C; Cq), 129.8 (1C; CHarom), 131.8 (2C; CHarom), 132.1 (1C; CHarom),
133.0 (1C; Cq), 148.0 (1C; Cq), 159.3 (1C; Cq), 166.9 (1C; C=O).
163
Literature reference No.: [147]
CAS No.: 813460-03-6
Experiment 8
3-(4-fluorobenzyl)-3-hydroxy-2-methylisoindolin-1-one (67e) (SG-41)
N
O
CH3
HO F
C16H14FNO2Mol. Wt.: 271.29 g/mol
General procedure (A) was followed using NMP (0.2 g, 1.52 mmol), 4-fluoro-
phenylacetic acid (0.7 g, 4.51 mmol) and K2CO3 (0.3 g, 2.27 mmol). After 2 hr the
TLC showed a product was formed. The solution was cloudy and a very pale yellow
in colour. The crude yield was found to be 0.4 g. The crude product was washed by
adding a small amount of acetone to the round bottom flask, swirling and removing
the solvent. This was repeated several times and the product seen to be a colourless
powder which was confirmed to be the pure product by 1H-NMR. The yield of the
pure product was 0.1 g (0.55 mmol, 36%).
1H–NMR: (400 MHz, C2D6CO): δ (ppm) = 3.09 (s; 3H; NCH3), 3.35 (d; 2J =
13.6Hz; 1H; CH2), 3.53 (d; 2J = 14.0Hz; 1H; CH2), 5.44 (br.s; 1H; OH), 6.87 (m; 2H;
CHarom), 6.99 (m; 2H; CHarom), 7.43-7.51 (br.m; 2H; CHarom), 7.59 (m; 2H; CHarom). 13C–NMR: (100 MHz, C2D6CO): δ (ppm) = 23.9 (1C; NCH3), 41.9 (1C; CH2), 90.8
(1C; COH), 114.8 (1C; CHarom), 115.0 (1C; CHarom), 122.6 (1C; CHarom), 123.5 (1C;
CHarom), 129.5 (1C; CHarom), 131.9 (1C; CHarom), 132.3 (1C; CHarom), 132.4 (1C;
CHarom), 132.7 (1C; Cq), 147.9 (1C; Cq), 160.8 (1C; Cq), 163.2 (1C; Cq), 166.6 (1C;
C=O).
Melting point: 149-152oC
164
CAS No.: 1197385-26-4
Experiment 9
3-(4-Chlorobenzyl)-3-hydroxy-2-methylisoindolin-1-one (67f) (SG-2)
N
O
CH3
HO Cl
C16H14ClNO2Mol. Wt.: 287.74 g/mol
General procedure (A) was followed using NMP (0.2 g, 1.49 mmol), 2-(4-
chlorophenyl) acetic acid (0.8 g, 4.50 mmol) and K2CO3 (0.3 g, 2.25 mmol). After 5
hr the TLC showed the product was formed. The solution was cloudy yellow in
colour. The crude yield was found to be 0.5 g. Following column chromatography it
was assumed from the TLC that the desired product was collected in the second
fraction. The NMR obtained confirmed this and the yield was found to be 0.1 g (0.43
mmol, 29%). The product was initially an oily substance but when left overnight a
solid, colourless, wax-like product formed. The crude 1H-NMR revealed that only
52% of the starting material had reacted, and therefore the % yield was calculated
based on the conversion factor as 56%.
1H–NMR: (400 MHz, CDCl3) : δ (ppm) = 2.71 (s; 3H; NCH3), 3.30 (br.s; 1H; OH),
3.46 (d; 2J = 14.0Hz; 1H; CH2), 3.60 (d; 2J = 14.4Hz; 1H; CH2), 7.01 (d; 3J = 8.4Hz;
2H; CHarom), 7.09 (d; 3J = 8.4Hz; 2H; CHarom ), 7.35 (m; 1H; CHarom), 7.39-7.44
(br.m; 2H; CHarom), 7.65 (m; 1H; CHarom). 13C–NMR: (100 MHz, CDCl3): δ (ppm) = 23.8 (1C; NCH3), 41.7 (1C; CH2), 90.5
(1C; COH), 122.4 (1C; CHarom), 123.3 (1C; CHarom), 129.3 (2C; CHarom), 130.2 (1C;
CHarom), 131.9 (1C; Cq), 132.4 (1C; CHarom), 133.2 (2C; CHarom), 133.6 (1C; Cq),
133.8 (1C; Cq), 145.6 (1C; Cq), 167.8 (1C; C=O).
Melting point: 90-94oC
CAS No.: 1197385-27-5
165
Experiment 10
3-(3,4-Dichlorobenzyl)-3-hydroxy-2-methylisoindolin-1-one (67 g) (SG-5)
N
O
CH3
HO Cl
Cl
C16H13Cl2NO2Mol. Wt.: 322.19 g/mol
General procedure (A) was followed using NMP (0.2 g, 1.50 mmol), 3,4-dichloro-
phenylacetic acid (0.9 g, 4.50 mmol) and K2CO3 (0.3 g, 2.25 mmol). After 3 hr the
TLC showed a product was formed. Following column chromatography it was
assumed from the TLC that the desired product was collected in fraction 4. The 1H-
NMR obtained confirmed this and the yield was found to be 0.3 g, (0.80 mmol,
53%). The product formed a colourless, flaky, powder-like substance.
1H–NMR: (400 MHz, CDCl3): δ (ppm) = 2.80 (s; 3H; NCH3), 2.95 (d; 2J = 14.0Hz;
1H; CH2), 3.40 (d; 2J = 13.6Hz; 1H; CH2), 3.98 (br.s; 1H; OH), 6.72 (dd; 3J = 8.4Hz; 4J = 2.4Hz; 1H; CHarom) 7.02 (d; 4J = 2.0Hz; 1H; CHarom), 7.18 (m; 2H; CHarom), 7.34
(ddd; 3J = 7.2Hz; 4J = 1.2Hz; 1H; CHarom), 7.40 (m; 1H; CHarom), 7.48 (ddd; 3J =
7.2Hz; 4J = 1.2Hz; 1H; CHarom). 13C–NMR: (100 MHz, CDCl3): δ (ppm) = 23.9 (1C; NCH3), 41.7 (1C; CH2), 90.1
(1C; COH), 122.7 (1C; CHarom), 123.2 (1C; CHarom), 129.4 (1C; CHarom), 129.8 (1C;
CHarom), 129.9 (1C; CHarom), 130.9 (1C; Cq), 131.2 (1C; Cq), 131.9 (1C; CHarom),
132.1 (1C; CHarom), 134.8 (1C; Cq), 145.7 (1C; Cq), 167.0 (1C; C=O).
Mass spec: [MS + Na]: 346 m/z; expected 322 m/z
Melting point: 149-151oC
CAS No.: 1197385-28-6
166
Experiment 11
3-(2-bromobenzyl)-3-hydroxy-2-methylisoindolin-1-one (67h) (SG-42)
N
O
CH3
HO
C16H14BrNO2Mol. Wt.: 332.19
Br
General procedure (A) was followed using NMP (0.2 g, 1.52 mmol), 2-
bromophenylacetic acid (1.0 g, 4.50 mmol) and K2CO3 (0.3 g, 2.26 mmol). After 5 hr
the TLC showed a product was formed. The solution was cloudy and milky. The
crude yield was found to be 0.4 g. The crude product was washed by adding a small
amount of acetone to the round bottom flask, swirling and removing the solvent. This
was repeated several times and the product seen to be a pale yellow powder which
was confirmed to be the pure product by 1H-NMR. The yield of the pure product was
0.2 g (0.53 mmol, 35%).
1H–NMR: (400 MHz, C2D6CO): δ (ppm) = 3.05 (s; 3H; NCH3), 3.39 (d; 2J =
14.0Hz; 1H; CH2), 3.70 (d; 2J = 14.0Hz; 1H; CH2), 6.45 (br.s; 1H; OH), 7.15 (ddd; 3J
= 7.2Hz; 4J = 1.6Hz; 1H; CHarom), 7.24 (ddd; 3J = 8.0Hz; 4J = 1.2Hz; 2H; CHarom),
7.30 (ddd; 3J = 8.0Hz; 4J = 1.2Hz; 1H; CHarom), 7.45-7.52 (br.m; 3H; CHarom), 7.60
(m; 1H; CHarom). 13C–NMR: (100 MHz, C2D6CO): δ (ppm) = 24.0 (1C; NCH3), 42.3 (1C; CH2), 90.3
(1C; COH), 122.7 (1C; CHarom), 123.7 (1C; CHarom), 126.3 (1C; Cq), 127.7 (1C;
CHarom), 129.3 (1C; CHarom), 129.6 (1C; CHarom), 131.8 (1C; CHarom), 132.4 (1C;
CHarom), 132.5 (1C; Cq), 133.1 (1C; CHarom), 136.1 (1C; Cq), 147.8 (1C; Cq), 166.6
(1C; C=O).
Mass spec: [MS + Na]: 355 m/z; expected 332 m/z
Melting point: 173-177oC
167
CAS No.: 1197385-29-7
Experiment 12
3-benzhydryl-3-hydroxy-2-methylisoindolin-1-one (67i) (SG-207)
N
O
HO
CH3
C22H19NO2Mol. Wt.: 329.39 g/mol
General procedure (A) was followed using NMP (0.24 g, 1.50 mmol), diphenylacetic
acid (0.96 g, 4.50 mmol) and K2CO3 (0.31 g, 2.26 mmol). The reaction was
monitored for CO2 formation by bubbling the N2 supply through the reaction solution
and then into a saturated barium hydroxide solution. After 3.5 hr the CO2 test was
negative. A precipitate was visible at the end of the reaction which was filtered
before solvent evaporation. The 1H-NMR showed this to be the pure product, which
was a colourless powder with a yield of 0.12 g (0.36 mmol; 24%). The filtrate was
then worked up as usual and the crude material found to be 0.40 g. The 1H-NMR
showed this to be the desired product with some impurities also present. The crude
product was purified, in the round bottom flask, by adding a small amount of acetone
to dissolve the impurities and then removing the solvent. This was repeated several
times and the product found to be a yellow powder with a yield of 0.3 g (0.78 mmol;
52%). The resulting 1H-NMR showed this to be the pure product.
1H–NMR: (400 MHz, C2D6CO): δ (ppm) = 2.70 (s; 3H; NCH3), 4.76 (s; 1H; CH),
6.39 (br.s; 1H; OH), 6.56 (dd; 3J = 7.6Hz; 4J = 0.8Hz; 1H; CHarom), 7.00 (m; 2H;
CHarom), 7.18 (m; 3H; CHarom), 7.23-7.31 (br.m; 3H; CHarom), 7.36 (ddd; 3J = 7.6Hz; 4J = 1.2Hz; 1H; CHarom), 7.50 (m; 3H; CHarom), 7.65 (dd; 3J = 7.6Hz; 4J = 0.8Hz; 1H;
CHarom). 13C–NMR: (100 MHz, C2D6CO): δ (ppm) = 24.3 (1C; NCH3), 59.1 (1C; CH), 92.2
(1C; C-OH), 123.2 (1C; CHarom), 125.2 (1C; CHarom), 127.7 (1C; CHarom), 127.8 (1C;
168
CHarom), 128.4 (2C; CHarom), 129.0 (2C; CHarom), 130.2 (2C; CHarom), 130.2 (1C;
CHarom), 131.6 (2C; CHarom), 131.7 (1C; CHarom), 133.9 (1C; Cq), 140.2 (1C; Cq),
140.6 (1C; Cq), 147.2 (1C; Cq), 166.8 (1C; C=O).
Literature reference No.: [148]
CAS No.: 147119-33-3
Experiment 13
3-(2-methylbenzyl)-3-hydroxy-2-methylisoindolin-1-one (67j) (SG-297)
N
HO
O
H3C
CH3
C17H17NO2Mol. Wt.: 267.32 g/mol
General procedure (A) was followed using NMP (0.24 g, 1.50 mmol), o-tolylacetic
acid (0.68 g, 4.50 mmol) and K2CO3 (0.31 g, 2.25 mmol). After 3 hr the reaction was
stopped and the precipitate, which had formed during the reaction, was filtered after
evaporating the acetone. This was found to be an off-white powder with a yield of
0.20 g, (0.77 mmol; 51%). The 1H-NMR showed this to be the desired product. The
filtrate was then worked up and the crude material found to have a yield of 0.19 g.
The 1H-NMR showed this to be the desired product with some impurities present.
This was purified by adding a small amount of acetone to dissolve the impurities and
then removing the solvent. The pure product was found to be an off-white solid with
a yield of 0.05 g, (0.18 mmol; 12%). The 1H-NMR showed this to be the pure
product. [Overall yield = 63%].
1H–NMR: (400 MHz, C2D6CO): δ (ppm) = 2.04 (s; 3H; CH3), 3.06 (s; 3H; NCH3),
3.08 (d; 3J = 15.6Hz; 1H; CH2), 3.58 (d; 3J = 14.0Hz; 1H; CH2), 5.40 (br.s; 1H; OH),
6.96 (dd; 3J = 6.8Hz; 4J = 1.2Hz; 1H; CHarom), 7.09-7.17 (br.m; 3H; 3 × CHarom), 7.24
169
(m; 1H; CHarom), 7.42 (ddd; 3J = 7.2Hz; 4J = 1.2Hz; 1H; CHarom), 7.46 (ddd; 3J =
7.2Hz; 4J = 1.2Hz; 1H; CHarom), 7.61 (dd; 3J = 6.8Hz; 4J = 1.2Hz; 1H; CHarom). 13C–NMR: (100 MHz, C2D6CO): δ (ppm) = 19.8 (1C; CH3), 23.9 (1C; NCH3), 39.5
(1C; CH2), 90.4 (1C; C-OH), 122.6 (1C; CHarom), 123.4 (1C; CHarom), 125.7 (1C;
CHarom), 127.1 (1C; CHarom), 129.4 (1C; CHarom), 130.3 (1C; CHarom), 131.1 (1C;
CHarom), 131.5 (1C; CHarom), 131.9 (1C; Cq), 134.6 (1C; Cq), 137.4 (1C; Cq), 147.7
(1C; Cq), 166.5 (1C; C=O).
Melting point: 146-148oC
Literature reference No.: [18]
CAS No.: 57445-03-1
Experiment 14
3-(2-(trifluoromethyl)benzyl)-3-hydroxy-2-methylisoindolin-1-one (67k) (SG-
308)
N
O
HO
C17H14F3NO2Mol. Wt.: 321.29 g/mol
CH3
F
FF
General procedure (A) was followed using NMP (0.24 g, 1.50 mmol), 2-(2-
(trifluoromethyl)phenyl)acetic acid (0.92 g, 4.50 mmol) and K2CO3 (0.31 g, 2.25
mmol). After 7 hr the reaction was stopped and the precipitate, which had formed
during the reaction, was filtered after evaporating the acetone. This was found to be
an off-white powder with a yield of 0.22 g, (0.69 mmol; 46%). The 1H-NMR showed
this to be the desired pure product. The filtrate was then worked up and the crude
material found to have a yield of 0.05 g. The 1H-NMR showed this to be the desired
product with some impurities present. This was not attempted to be purified.
170
1H–NMR: (400 MHz, C2D6CO): δ (ppm) = 3.02 (s; 3H; NCH3), 3.32 (d; 2J =
14.4Hz; 1H; CH2), 3.77 (d; 2J = 14.4Hz; 1H; CH2), 5.55 (br.s; 1H; OH), 6.84 (d; 3J =
7.6Hz; 1H; CHarom), 7.40 (ddd; 3J = 7.6Hz; 4J = 1.2Hz; 1H; CHarom), 7.47 (ddd; 3J =
7.2Hz; 4J = 1.2Hz; 1H; CHarom), 7.52 (d; 3J = 7.6Hz; 1H; CHarom), 7.64 (m; 2H;
CHarom), 7.68 (d; 3J = 8.0Hz; 1H; CHarom), 7.78 (d; 3J = 8.0Hz; 1H; CHarom). 19F–NMR: (400 MHz, C2D6CO / C6F6): δ (ppm) = -59.2 (s; 3F; CF3). 13C–NMR: (100 MHz, C2D6CO): δ (ppm) = 23.8 (1C; NCH3), 39.6 (1C; CH2), 90.2
(1C; C-OH), 123.2 (1C; CHarom), 123.6 (1C; CHarom), 126.6 (1C; Cq), 126.8 (1C;
Cq), 128.1 (1C; CHarom), 129.8 (1C; Cq), 130.1 (1C; CHarom), 132.1 (1C; CHarom),
132.5 (1C; CHarom), 132.6 (1C; CHarom), 133.1 (1C; CHarom), 136.0 (1C; Cq), 147.8
(1C; Cq), 168.6 (1C; C=O).
Melting point: 189-190oC
Experiment 15
3-benzyl-3-hydroxy-2-methylisoindolin-1-one (67a) (SG-239)
N
O
CH3
HO
C16H15NO2Mol. Wt.: 253.3 g/mol
General procedure (A) was followed, with the slight variation of halving all amounts
used and using a 50 ml reaction flask, using NMP (0.12 g, 0.75 mmol), L-3-
phenyllactic acid (0.37 g, 2.24 mmol) and K2CO3 (0.15 g, 1.11 mmol). After 4 hr the
TLC showed the product was formed. The solution had changed from a pale yellow
to a bright yellow in colour. The crude material was found to be 0.23 g and the 1H-
NMR showed that this was the desired product with some impurities present
including the acetone aldol in quite a substantial amount. Column chromatography
was performed using solvent system ethyl acetate:hexane (1:1) and the pure product
collected in fractions9-11. The pure product was seen to be a colourless solid with a
yield of 0.04 g (0.16 mmol; 21%).
171
1H–NMR: (400 MHz, C2D6CO): δ (ppm) = 3.04 (s; 3H; NCH3), 3.31 (d; 2J =
14.0Hz; 1H; CH2), 3.50 (d; 2J = 14.0Hz; 1H; CH2), 5.51 (br.s; 1H; OH), 6.92 (m; 2H;
CHarom), 7.06 (m; 3H; CHarom), 7.40 (m; 1H; CHarom), 7.44 (dd; 3J = 7.6Hz; 4J =
1.2Hz; 1H; CHarom), 7.54 (dd; 3J = 4.4Hz; 4J = 1.2Hz; 2H; CHarom).
For 13C-NMR data see experiment 4.
7.1.2 General Procedure (A1):
As in General Procedure A, substituting distilled water for pH7 buffer. Work-up
differs by washing with sat. NHCl4 instead of sat. NaHCO3.
Experiment 16
3-(2-iodobenzyl)-3-hydroxy-2-methylisoindolin-1-one (67b) (SG-247)
N
O
CH3
HO CH3
C17H17NO2Mol. Wt.: 267.32 g/mol
General procedure (A) was followed using NMP (0.2 g, 1.50 mmol), p-tolylacetic
acid (0.7 g, 4.50 mmol) and K2CO3 (0.3 g, 2.26 mmol). The solution was irradiated
for 4 hr and the crude product found to be 0.5 g. Following purification by washing
with acetone the pure yield was found to be 0.1 g (0.48 mmol; 32%).
For 1H-NMR data see experiment 5.
172
Experiment 17
3-(4-methylbenzyl)-3-hydroxyisoindolin-1-one (68a) (SG-284)
NH
O
HO CH3
C16H15NO2Mol. Wt.: 253.3 g/mol
General procedure (A1) was followed using phthalimide (0.22 g, 1.50 mmol), p-
tolylacetic acid (0.68 g, 4.50 mmol) and K2CO3 (0.31 g, 2.25 mmol). After 3 hr the
reaction was worked up and the crude material found to have a yield of 0.35 g, (1.38
mmol; 92%). The 1H-NMR showed this to be the desired product.
1H–NMR: (400 MHz, C2D6CO): δ (ppm) = 2.22 (s; 3H; CH3), 3.34 (d; 3J = 13.2Hz;
1H; CH2), 3.42 (d; 3J = 13.2Hz; 1H; CH2), 5.41 (br.s; 1H; OH), 6.95 (d; 3J = 8.0Hz;
2H; CHarom), 7.02 (d; 3J = 8.4Hz; 2H; CHarom), 7.45 (m; 1H; CHarom), 7.49 (dd; 3J =
7.6Hz; 4J = 1.2Hz; 1H; CHarom), 7.62 (dd; 3J = 4.4Hz; 4J = 1.2Hz; 2H; CHarom), 7.90
(br.s; 1H; NH). 13C–NMR: (100 MHz, C2D6CO): δ (ppm) = 21.0 (1C; CH3), 45.2 (1C; CH2), 88.6
(1C; C-OH), 123.3 (1C; CHarom), 123.6 (1C; CHarom), 129.1 (2C; CHarom), 129.7 (1C;
CHarom), 131.4 (2C; CHarom), 132.5 (1C; CHarom), 133.0 (1C; Cq), 133.6 (1C; Cq),
136.5 (1C; Cq), 149.6 (1C; Cq), 168.4 (1C; C=O).
CAS No.: 1246376-41-9
Experiment 18
3-(4-fluorobenzyl)-3-hydroxy-2-methylisoindolin-1-one (67e) (SG-248)
N
O
CH3
HO F
C16H14FNO2Mol. Wt.: 271.29 g/mol
173
General procedure (A) was followed using NMP (0.24 g, 1.50 mmol), 4-fluoro-
phenylacetic acid (0.69 g, 4.51 mmol) and K2CO3 (0.31 g, 2.26 mmol). The solution
was irradiated for 4 hr and following work-up, the crude product was found to be 0.4
g. Following purification by washing with acetone, the pure yield was found to be
0.2 g (0.59 mmol; 39%).
For 1H-NMR data see experiment 8.
Experiment 19
3-(4-fluorobenzyl)-3-hydroxyisoindolin-1-one (68b) (SG-285)
NH
O
HO F
C15H12FNO2Mol. Wt.: 257.26 g/mol
General procedure (A1) was followed using phthalimide (0.22 g, 1.50 mmol), 4-
fluorophenylacetic acid (0.69 g, 4.50 mmol) and K2CO3 (0.31 g, 2.26 mmol). After 3
hr the reaction was worked up and the crude material found to have a yield of 0.33 g,
(1.28 mmol; 85%). The 1H-NMR showed this to be the desired product.
1H–NMR: (400 MHz, C2D6CO): δ (ppm) = 3.38 (d; 2J = 13.6Hz; 1H; CH2), 3.45 (d; 2J = 13.6Hz; 1H; CH2), 5.49 (br.s; 1H; OH), 6.91 (dd; 3J = 8.8Hz; 4J = 2.0Hz; 2H;
CHarom), 7.18 (dd; 3J = 8.8Hz; 4J = 2.0Hz; 2H; CHarom), 7.46 (ddd; 3J = 6.0Hz; 4J =
1.6Hz; 1H; CHarom) 7.50 (m; 1H; CHarom), 7.62 (m; 2H; CHarom), 7.95 (br.s; 1H; NH). 13C–NMR: (100 MHz, C2D6CO): δ (ppm) = 44.8 (1C; CH2), 88.5 (1C; C-OH), 114.9
(1C; CHarom), 115.1 (1C; CHarom), 123.3 (1C; CHarom), 123.6 (1C; CHarom), 129.9
(1C; CHarom), 132.7 (1C; CHarom), 132.8 (1C; Cq), 132.9 (1C; Cq), 133.2 (1C;
CHarom), 133.3 (1C; CHarom), 149.3 (1C; Cq), 161.1 (1C; Cq), 168.4 (1C; C=O).
CAS No.: 1246376-43-1
174
Experiment 20
3-(2-methylbenzyl)-3-hydroxyisoindolin-1-one (68c) (SG-296)
NH
HO
O
H3C
C16H15NO2Mol. Wt.: 253.3 g/mol
General procedure (A1) was followed using phthalimide (0.22 g, 1.50 mmol), o-
tolylacetic acid (0.67 g, 4.50 mmol) and K2CO3 (0.31 g, 2.26 mmol). After 3 hr the
reaction was worked up and the crude material found to have a yield of 0.46 g. This
was purified by adding a small amount of acetone to dissolve the impurities and then
removing the solvent. The pure product was found to be a yellow solid with a yield
of 0.21 g, (0.85 mmol; 57%). The 1H-NMR showed this to be the desired product.
1H–NMR: (400 MHz, C2D6CO): δ (ppm) = 2.25 (s; 3H; CH3), 3.37 (d; 3J = 14.0Hz;
1H; CH2), 3.42 (d; 3J = 14.0Hz; 1H; CH2), 5.35 (br.s; 1H; OH), 7.07 (m; 1H;
CHarom), 7.12 (dd; 3J = 5.2Hz; 4J = 1.2Hz; 2H; CHarom), 7.25 (d; 3J = 7.6Hz; 1H;
CHarom), 7.43 (m; 1H; CHarom), 7.50 (ddd; 3J = 7.6Hz; 4J = 1.2Hz; 1H; CHarom), 7.58
(ddd; 3J = 7.6Hz; 4J = 1.2Hz; 2H; CHarom), 7.78 (br.s; 1H; NH). 13C–NMR: (100 MHz, C2D6CO): δ (ppm) = 20.3 (1C; CH3), 42.6 (1C; CH2), 88.7
(1C; C-OH), 123.4 (1C; CHarom), 123.7 (1C; CHarom), 126.0 (1C; CHarom), 127.5 (1C;
CHarom), 129.9 (1C; CHarom), 130.9 (1C; CHarom), 132.4 (1C; CHarom), 132.5 (1C;
CHarom), 132.7 (1C; Cq), 135.3 (1C; Cq), 138.3 (1C; Cq), 150.0 (1C; Cq), 168.1 (1C;
C=O).
Melting point: 129-130oC
CAS No.: 1246376-48-6
175
Experiment 21
3-(2-(trifluoromethyl)benzyl)-3-hydroxyisoindolin-1-one (68d) (SG-311)
NH
O
HO
F
FF
C16H12F3NO2Mol. Wt.: 307.27 g/mol
General procedure (A1) was followed using phthalimide (0.22 g, 1.51 mmol), 2-(2-
(trifluoromethyl)phenyl)acetic acid (0.92 g, 4.50 mmol) and K2CO3 (0.31 g, 2.25
mmol). After 6 hr the reaction was stopped and the precipitate, which had formed
during the reaction, was filtered after evaporating the acetone. This was found to be
an off-white powder with a yield of 0.19 g, (0.61 mmol; 40%). The 1H-NMR showed
this to be the desired pure product. The filtrate was then worked up and the crude
material found to have a yield of 0.10 g (0.34 mmol; 23%). The 1H-NMR confirmed
this to be the desired product. [Overall yield = 63%].
1H–NMR: (400 MHz, C2D6CO): δ (ppm) = 3.56 (d; 2J = 14.4Hz; 1H; CH2), 3.62 (d; 2J = 14.4Hz; 1H; CH2), 5.60 (br.s; 1H; OH), 7.31 (d; 3J = 7.2Hz; 1H; CHarom), 7.47
(d; 3J = 7.6Hz; 1H; CHarom), 7.52 (ddd; 3J = 7.2Hz; 4J = 1.2Hz; 1H; CHarom), 7.57 (m;
1H; CHarom), 7.58 (ddd; 3J = 7.2Hz; 4J = 1.2Hz; 1H; CHarom), 7.62 (dd; 3J = 7.2Hz; 4J
= 0.8Hz; 1H; CHarom), 7.70 (d; 3J = 7.6Hz; 1H; CHarom), 7.78 (d; 3J = 7.6Hz; 1H;
CHarom), 7.90 (br.s; 1H; NH). 19F–NMR: (400 MHz, C2D6CO/C6F6): δ (ppm) = -58.7 (s; 3F; CF3). 13C–NMR: (100 MHz, C2D6CO / C6F6): δ (ppm) = 41.7 (1C; CH2), 88.0 (1C; C-
OH), 123.4 (1C; CHarom), 123.5 (1C; CHarom), 126.5 (1C; Cq), 126.8 (1C; Cq), 128.0
(1C; CHarom), 129.8 (1C; Cq), 130.0 (1C; CHarom), 132.3 (1C; CHarom), 132.4 (1C;
CHarom), 132.7 (1C; CHarom), 133.6 (1C; CHarom), 135.7 (1C; Cq), 149.7 (1C; Cq),
168.2 (1C; C=O).
Melting point: 136-138oC
176
7.1.3 General Procedure (B):
For these experiments a variation of general procedure (A) was used. In these cases
the addition partners were sodium salts so, as there was no need for deprotonation by
K2CO3, this was not used. The NMP was dissolved in 10 ml of acetone as usual and
the addition partner dissolved in 10 ml of distilled H2O. These were then mixed
together and general procedure (A) followed as usual.
Experiment 22
(R) and (S)-3-hydroxy-3-isopropyl-2-methylisoindolin-1-one (69a/66a) (SG-34)
N
O
HO
CH3
C12H15NO2Mol. Wt.: 205.25 g/mol
General procedure (B) was followed using NMP (0.2 g, 1.50 mmol) and sodium 3-
methyl-2-oxobutanoate (0.6 g, 4.51 mmol). After 3 hr the TLC showed the product
had been formed. The solution was clear and a luminous yellow in colour. The crude
material was found to be 0.2 g. Following column chromatography it was assumed
from the TLC, that the desired product was collected in fraction 4. The 1H-NMR
obtained confirmed this and the yield was found to be 0.1 g (0.44 mmol, 29%). The
product was a colourless powder.
1H–NMR: (400 MHz, C2D6CO): δ (ppm) = 0.55 (d; 3J = 6.8Hz; 3H; CH3), 1.25 (d; 3J
= 6.8Hz; 3H; CH3), 2.47 (m; 1H; CH), 2.95 (s; 3H; NCH3) 5.23 (br.s; 1H; OH), 7.54
(ddd; 3J = 7.2Hz; 4J = 1.2Hz; 1H; CHarom), 7.62 (ddd; 3J = 7.6Hz; 4J = 1.2Hz; 1H;
CHarom), 7.65-7.70 (br.m; 2H; CHarom). 13C–NMR: (100 MHz, C2D6CO): δ (ppm) = 16.8 (1C; CH3), 17.5 (1C; CH3), 23.6
(1C; NCH3), 34.7 (1C; CH), 93.2 (1C; COH), 123.1 (1C; CHarom), 124.2 (1C;
CHarom), 129.8 (1C; CHarom), 132.0 (1C; CHarom), 133.7 (1C; Cq), 146.7 (1C; Cq),
166.9 (1C; C=O).
Literature reference No.: [132]
177
CAS No.: 32360-86-4
Experiment 23
3-(3-methylbutanoyl)-3-hydroxy-2-methylisoindolin-1-one (70b) (SG-37)
N
O
HO
CH3
O
C14H17NO3Mol. Wt.: 247.29 g/mol
General procedure (B) was followed using NMP (0.2 g, 1.55 mmol) and sodium 4-
methyl-2-oxopentanoate (0.7 g, 4.51 mmol). After 4.5 hr the TLC showed the
product was formed. The solution was clear and yellow-orange in colour. The crude
material was found to be 0.4 g. Following column chromatography it was assumed
from the TLC, that the desired product was collected in fraction 4. The 1H-NMR
obtained confirmed this and the yield was found to be 0.1 g (0.41 mmol, 26%). The
product was a yellow, slightly oily powder.
1H–NMR: (400 MHz, C2D6CO): δ (ppm) = 0.80 (d; 3J = 6.8Hz; 3H; CH3), 0.86 (d; 3J
= 6.8Hz; 3H; CH3), 2.13 (m; 1H; CH), 2.32 (dd; 2J = 18.0Hz; 3J = 6.8Hz 1H; CH2),
2.48 (dd; 2J = 18.0Hz; 3J = 6.8Hz 1H; CH2), 2.89 (s; 3H; NCH3), 6.16 (br.s; 1H;
OH), 7.59 (m; 1H; CHarom), 7.64-7.72 (br.m; 2H; CHarom), 7.80 (m; 1H; CHarom). 13C–NMR: (100 MHz, C2D6CO): δ (ppm) = 23.2 (1C; CH3), 23.2 (1C; CH3), 25.1
(1C; CH), 25.4 (1C; NCH3), 46.3 (1C; CH2), 93.7 (1C; C-OH), 124.1 (1C; CHarom),
124.7 (1C; CHarom), 131.9 (1C; CHarom), 133.2 (1C; Cq), 133.9 (1C; CHarom), 145.3
(1C; Cq), 168.6 (1C; C=O), 195.5 (1C; C=O).
Literature reference No.: [132]
CAS No.: 556067-40-4
178
Experiment 24
3-tert-butyl-3-hydroxy-2-methylisoindolin-1-one (69c) (SG-33)
N
O
HO
CH3
C13H17NO2Mol. Wt.: 219.28 g/mol
General procedure (B) was followed using NMP (0.2 g, 1.53 mmol) and sodium 3,3-
dimethyl-2-oxobutanoate (0.7 g, 4.51 mmol). After 2.5 hr the TLC showed the
product was formed. The solution was clear and a luminous yellow in colour. The
crude material was found to be 0.4 g. Following column chromatography it was
assumed from the TLC, that the desired product was collected in the second fraction.
The 1H-NMR obtained confirmed this and the yield was found to be 0.2 g (1.04
mmol, 69%). The product was a colourless powder.
1H–NMR: (400 MHz, C2D6CO): δ (ppm) = 1.08 (s; 9H; 3×CH3), 3.06 (s; 3H; NCH3)
5.26 (br.s; 1H; OH), 7.52 (ddd; 3J = 7.2Hz; 4J = 1.2Hz; 1H; CHarom), 7.59 (ddd; 3J =
7.6Hz; 4J = 1.2Hz; 1H; CHarom), 7.68 (t; 3J = 8.0Hz; 2H; CHarom). 13C–NMR: (100 MHz, C2D6CO): δ (ppm) = 26.6 (3C; 3 × CH3), 27.7 (1C; NCH3)
40.4 (1C; Cq), 95.0 (1C; COH), 122.9 (1C; CHarom), 125.1 (1C; CHarom), 129.7 (1C;
CHarom), 131.6 (1C; CHarom), 133.8 (1C; Cqarom), 148.8 (1C; Cqarom), 168.0 (1C;
C=O).
Literature reference No.: [132]
CAS No.: 39563-77-4
179
Experiment 25
Like and Unlike-3-sec-butyl-3-hydroxy-2-methylisoindolin-1-one (69d) (SG-35)
N
O
HO
CH3
C13H17NO2Mol. Wt.: 219.28 g/mol
N
O
HO
CH3
General procedure (B) was followed using NMP (0.2 g, 1.53 mmol) and sodium 3-
methyl-2-oxopentanoate (0.7 g, 4.52 mmol). After 3 hr the TLC showed both
isomers of the product had been formed. The solution was clear and a luminous
yellow in colour. The crude material was found to be 0.3 g. Following column
chromatography it was assumed from the TLC, that the desired product was collected
in fraction 3. The 1H-NMR obtained confirmed this; however both isomers were
present in a ratio of 53:47. The yield was found to be 0.1 g (0.60 mmol, 39%). The
product was a colourless powder.
Major Isomer: 1H–NMR: (400 MHz, C2D6CO): δ (ppm) = 0.53 (d; 3J = 6.8Hz; 3H; CH3), 1.02 (t; 3J
= 7.6Hz; 3H; CH3), 1.30 (m; 1H; CH), 2.19 (m; 2H; CH2), 2.94 (s; 3H; NCH3) 5.24
(br.s; 1H; OH), 7.53 (m; 1H; CHarom), 7.62 (m; 2H; CHarom), 7.68 (m; 1H; CHarom).
Minor Isomer: 1H–NMR: (400 MHz, C2D6CO): δ (ppm) = 0.46 (m; 1H; CH), 0.85 (t; 3J = 7.6Hz;
3H; CH3), 1.23 (d; 3J = 6.8Hz; 3H; CH3), 2.19 (m; 2H; CH2), 2.94 (s; 3H; NCH3)
5.22 (br.s; 1H; OH), 7.53 (m; 1H; CHarom), 7.62 (m; 2H; CHarom), 7.68 (m; 1H;
CHarom).
Literature reference No.: [132]
CAS No.: 312909-75-4
180
Experiment 26
3-benzyl-3-hydroxy-2-methylisoindolin-1-one (69e/67a) (SG-36)
N
O
CH3
HO
C16H15NO2Mol. Wt.: 253.3 g/mol
General procedure (B) was followed using NMP (0.2 g, 1.52 mmol) and sodium 2-
oxo-3-phenylpropanoate (0.8 g, 4.50 mmol). After 6.5 hr the TLC showed the
product was formed. The solution was clear and yellow at this point. The crude
material was found to be 0.4 g. The crude product was then recrystallised from
acetone and the pure product found to be an off-white powder. The 1H-NMR
obtained confirmed this was the pure product, and the yield was found to be 0.2 g
(0.79 mmol, 52%).
1H–NMR: (400 MHz, C2D6CO): δ (ppm) = 3.09 (s; 3H; NCH3), 3.36 (d; 2J =
14.0Hz; 1H; CH2), 3.54 (d; 2J = 13.6Hz; 1H; CH2), 5.43 (br.s; 1H; OH), 6.96 (m; 2H;
CHarom), 7.10 (m; 3H; CHarom), 7.42-7.49 (br.m; 2H; CHarom), 7.59 (m; 2H; CHarom). 13C–NMR: (100 MHz, C2D6CO): δ (ppm) = 24.7 (1C; NCH3), 43.7 (1C; CH2), 91.9
(1C; C-OH), 123.7 (1C; CHarom), 124.5 (1C; CHarom), 128.1 (1C; CHarom), 129.3 (2C;
CHarom), 130.6 (1C; CHarom), 131.6 (2C; CHarom), 132.9 (1C; CHarom), 133.8 (1C; Cq),
137.0 (1C; Cq), 148.6 (1C; Cq), 167.5 (1C; C=O).
7.1.4 General Procedure (C):
The photoproduct was dissolved in DCM, then concentrated HCl was added and the
mixture stirred overnight. Distilled water (~25 ml) was added and the organic layer
extracted with DCM (3 × 25 ml), washed with saturated NaHCO3 (2 × 10 ml) and
saturated NaCl, dried over MgSO4, gravity filtered and the solvent evaporated to
afford the dehydrated photoproduct.
181
Experiment 27
(E) and (Z)-3-benzylidene-2-methylisoindolin-1-one (71a) (SG-57)
N
OC16H13NO
Mol. Wt.: 235.28 g/mol
CH3
Following general procedure (C), 67a (0.1 g; 0.47 mmol) was dissolved in ~12 ml of
DCM. Concentrated HCl (~4 ml) was added and the mixture stirred overnight. The 1H-NMR of the crude product confirmed the presence of both isomers of the desired
product, with the ratio calculated to be 90:10. The crude product was then purified by
column chromatography, using solvent system ethyl acetate:hexane 1:1, and the
product collected in fraction 1. The product appeared as a brown solid and had a
yield of 0.1 g; (0.32 mmol; 68%). The 1H-NMR showed this to be an isolated isomer
of the desired product.
1H–NMR: (400 MHz, C2D6CO): δ (ppm) = 3.36 (s; 3H; NCH3), 6.69 (s; 1H; CHolef),
7.35 (d; 3J = 7.6Hz; 1H; CHarom), 7.41 (m; 2H; CHarom), 7.48 (m; 5H; CHarom), 7.75
(d; 3J = 7.6Hz; 1H; CHarom). 13C–NMR: (100 MHz, C2D6CO): δ (ppm) = 26.1 (1C; NCH3), 111.0 (1C; CHolef),
123.5 (1C; CHarom), 123.7 (1C; CHarom), 128.6 (1C; CHarom), 129.5 (2C; CHarom),
130.2 (1C; CHarom), 130.4 (2C; CHarom), 131.6 (1C; Cq), 132.3 (1C; CHarom), 135.8
(1C; Cq), 136.2 (1C; Cq), 138.1 (1C; Cq), 166.3 (1C; C=O).
Literature reference No.: [149]
CAS No.: 4770-24-5
182
Experiment 28
(E) and (Z)-3-(4-methylbenzylidene)-2-methylisoindolin-1-one (71b) (SG-61)
N
O
CH3
H3C
C17H15NOMol. Wt.: 249.31 g/mol
Following general procedure (C), 67b (0.13 g; 0.47 mmol) was dissolved in 12 ml of
DCM. Concentrated HCl (4 ml) was added and the mixture stirred overnight. The 1H-NMR of the crude product confirmed the presence of both isomers of the desired
product, with the ratio calculated to be 91:9. The crude product was then purified by
column chromatography, using solvent system ethyl acetate:hexane 1:1, and the
product collected in fraction 1. The product appeared as a brown solid and had a
yield of 0.1 g; (0.29 mmol; 62%). The 1H-NMR showed this to also contain both
isomers of the desired product which meant full spectral data could not be
determined. However, some selected peaks are shown.
1H–NMR: (400 MHz, CDCl3): δ (ppm) =
Selected peaks for CH3:
Major isomer: 3.38 (s; 3H; CH3); Minor isomer: 3.05 (s; 3H; CH3).
Selected peaks for CHolef:
Major isomer: 6.49 (s; 1H; CHolef); Minor isomer: 6.75 (s; 1H; CHolef).
183
Experiment 29
(E) and (Z)-3-(3,4-dichlorobenzylidene)-2-methylisoindolin-1-one (71c) (SG-59)
N
OC16H11Cl2NO
Mol. Wt.: 304.17 g/mol
CH3
Cl
Cl
Following general procedure (C), 67 g (0.11 g; 0.35 mmol) was dissolved in 12 ml of
DCM. Concentrated HCl (4 ml) was added and the mixture stirred overnight. The 1H-NMR of the crude product confirmed the presence of both isomers of the desired
product, with the ratio calculated to be 82:18. The crude product was then purified by
washing with a small amount of acetone. The product appeared as a pale yellow, oily
solid and had a yield of 0.1 g; (0.26 mmol; 64%). The 1H-NMR showed this to also
contain both isomers of the desired product which meant full spectral data could not
be determined. However, some selected peaks are shown.
1H–NMR: (400 MHz, CDCl3): δ (ppm) =
Selected peaks for CH3:
Major isomer: 3.17 (s; 3H; CH3); Minor isomer: 2.85 (s; 3H; CH3).
Selected peaks for CHolef:
Major isomer: 6.46 (s; 1H; CHolef); Minor isomer: 6.18 (s; 1H; CHolef).
Mass spec: [MS]: 304 m/z; expected 304 m/z
Melting point: 129-132oC
184
Experiment 30
(E) and (Z)-3-(2-methylbenzylidene)isoindolin-1-one (71d) (SG-304)
N
O
CH3
C17H15NOMol. Wt.: 249.31 g/mol
CH3
Following general procedure (C) 67j (0.21 g; 0.78 mmol) was dissolved in ~15 ml of
DCM. Concentrated HCl (~4 ml) was added and the mixture stirred overnight. The
crude product had a yield of 0.19 g. The 1H-NMR showed the desired product had
been formed, however both isomers had been formed in a ratio of 85:15. Upon
purifying the product, by washing with a small amount of acetone then removing the
solvent, only one isomer remained. The pure product appeared as off-white, clear
crystals. The yield was found to be 0.11 g; (0.45 mmol; 58%).
1H–NMR: (400 MHz, C2D6CO): δ (ppm) = 2.35 (s; 3H; CH3), 3.43 (s; 3H; NCH3),
6.67 (s; 1H; Holef), 7.02 (dd; 3J = 8.0Hz; 4J = 0.8Hz; 1H; CHarom), 7.31 (m; 1H;
CHarom), 7.36-7.42 (br.m; 3H; 3 × CHarom), 7.43 (d; 3J = 7.6Hz; 1H; CHarom), 7.52
(ddd; 3J = 7.2Hz; 4J = 0.8Hz; 1H; CHarom), 7.79 (dd; 3J = 7.6Hz; 4J = 0.8Hz; 1H;
CHarom). 13C–NMR: (100 MHz, C2D6CO): δ (ppm) = 20.2 (1C; CH3), 26.1 (1C; NCH3), 109.8
(1C; CHolef), 123.4 (1C; CHarom), 123.6 (1C; CHarom), 126.8 (1C; CHarom), 129.0 (1C;
CHarom), 130.1 (1C; CHarom), 130.8 (1C; CHarom), 131.0 (1C; CHarom), 131.5 (1C; Cq),
132.4 (1C; CHarom), 135.6 (1C; Cq), 136.1 (1C; Cq), 137.9 (1C; Cq), 138.0 (1C; Cq),
166.4 (1C; C=O).
Melting point: 140-142oC
185
Experiment 31
(E) and (Z)-3-(2-methylbenzylidene)isoindolin-1-one (71e) (SG-303)
NH
OC16H13NO
Mol. Wt.: 235.28 g/mol
CH3
Following general procedure (C) 68c (0.21 g; 0.83 mmol) was dissolved in ~15 ml of
DCM. Concentrated HCl (~4 ml) was added and the mixture stirred overnight. The
crude product had a yield of 0.18 g. The 1H-NMR showed the desired product was
present, however both isomers were formed in a ratio of 76:24. Upon purifying the
product, by washing with a small amount of acetone then removing the solvent, it
was found that only one isomer remained. The yield was found to be 0.13 g; (0.56
mmol; 67%).
1H–NMR: (400 MHz, C2D6CO): δ (ppm) = 2.45 (s; 3H; CH3), 6.83 (s; 1H; Holef),
7.22-7.31 (br.m; 3H; 3 × CHarom), 7.62 (ddd; 3J = 7.6Hz; 4J = 0.8Hz; 2H; CHarom),
7.75 (ddd; 3J = 7.6Hz; 4J = 0.8Hz; 1H; CHarom), 7.83 (dd; 3J = 7.6Hz; 4J = 0.8Hz; 1H;
CHarom), 8.11 (d; 3J = 8.0Hz; 1H; CHarom), 9.46 (br.s; 1H; NH). 13C–NMR: (100 MHz, C2D6CO): δ (ppm) = 20.1 (1C; CH3), 104.3 (1C; CHolef),
121.0 (1C; CHarom), 123.4 (1C; CHarom), 127.0 (1C; CHarom), 128.0 (1C; CHarom),
129.7 (1C; CHarom), 130.0 (1C; Cq), 130.1 (1C; CHarom), 130.8 (1C; CHarom), 132.7
(1C; CHarom), 134.5 (1C; Cq), 134.6 (1C; Cq), 137.4 (1C; Cq), 139.4 (1C; Cq), 169.3
(1C; C=O).
Melting point: 188-190oC
186
7.2 Chapter 3: Photoaddition reactions of phthalimides with
heteroatom-containing addition partners
7.2.1 General Procedure (D):
The amino acid (5.0 mmol), glacial acetic acid (~30 ml) and acetic anhydride (1 ml)
were placed in a 50 ml round bottom flask. The solution was refluxed for 3 nights
and stirred at room temperature for a further 3 nights. The solvent was then distilled
off, the product dried under vacuum overnight, and a 1H-NMR obtained. The crude
product was washed several times with diethyl ether by adding ~3 ml, sonicating and
then removing the solvent. The pure product was then dried under vacuum and a
second 1H-NMR obtained.
Experiment 32
(S)-2-acetamido-3,3-dimethylbutanoic acid (72a) (SG-120)
NH
CO2H
O
C8H15NO3Mol. Wt.: 173.21 g/mol
General procedure (D) was followed using L-t-Leucine (0.7 g, 5.03 mmol).
Following purification, the 1H-NMR showed this to be pure product. The yield was
found to be 0.3 g (2.00 mmol; 40%). The product was an orange-brown solid.
1H–NMR: (400 MHz, CDCl3/5% TFA): δ (ppm) = 1.00 (s; 9H; 3 × CH3), 2.18 (s;
3H; CH3), 4.48 (d; 3J = 9.0Hz; 1H; CH), 7.42 (d; 3J = 9.0Hz; 1H; NH). 13C–NMR: (100 MHz, CDCl3/5% TFA): δ (ppm) = 21.4 (1C; CH3), 26.1 (3C; 3 ×
CH3), 34.6 (1C; Cq), 61.5 (1C; CH), 175.1 (1C; C=O), 175.5 (1C; C=O).
Literature reference No.: [150]
CAS No.: 22146-59-4
187
Experiment33
1-acetamidocyclohexanecarboxylic acid (72b) (SG-136)
CO2HNH
O
C9H15NO3Mol. Wt.: 185.22 g/mol
General procedure (D) was followed using 1-aminocyclohexane carboxylic acid (0.7
g, 5.0 mmol). No purification was necessary as the 1H-NMR showed this to be pure
product. The yield was found to be 0.9 g (4.77 mmol; 95%). The product was a
yellow-brown powder.
1H–NMR: (400 MHz, CDCl3/5% TFA): δ (ppm) = 1.42 (m; 3H; 2 × CH2), 1.72 (m;
3H; 2 × CH2), 1.94 (m; 2H; CH2), 2.09 (m; 2H; CH2), 2.22 (s; 3H; CH3), 6.60 (br.s;
1H; NH). 13C–NMR: (100 MHz, CDCl3/5% TFA): δ (ppm) = 21.2 (2C; 2 × CH2), 21.8 (1C;
CH3), 24.7 (1C; CH2), 32.0 (2C; 2 × CH2), 60.7 (1C; Cq), 175.4 (1C; C=O), 180.3
(1C; C=O).
Literature reference No.: [151]
CAS No.: 4854-47-1
Experiment 34
2-acetamido-2-methylpropanoic acid (72c) (SG-134)
CO2HNH
O
C6H11NO3Mol. Wt.: 145.16 g/mol
General procedure (D) was followed using 2-amino-2-methylpropanoic acid (0.5 g,
5.01 mmol). No purification was necessary as the 1H-NMR showed this to be pure
188
product. The yield was found to be 0.7 g (4.5 mmol; 89%). The product was a pale
yellow powder.
1H–NMR: (400 MHz, CDCl3/5% TFA): δ (ppm) = 1.63 (s; 6H; 2 × CH3), 2.19 (s;
3H; CH3), 6.86 (br.s; 1H; NH). 13C–NMR: (100 MHz, CDCl3/5% TFA): δ (ppm) = 21.8 (1C; CH3), 24.2 (2C; 2 ×
CH3), 57.9 (1C; Cq), 175.0 (1C; C=O), 180.3 (1C; C=O).
Literature reference No.: [152]
CAS No.: 5362-00-5
Experiment 35
2-acetamido-2-phenylacetic acid (72d) (SG-148)
CO2HNH
O
C10H11NO3Mol. Wt.: 193.2 g/mol
General procedure (D) was followed using 2-amino-2-phenylacetic acid (0.8 g, 5.01
mmol). Following purification, the 1H-NMR showed this to be pure product. The
yield was found to be 0.5 g (2.6 mmol; 51%). The product was a pale yellow powder.
1H–NMR: (400 MHz, CDCl3/5% TFA): δ (ppm) = 2.26 (s; 3H; CH3), 5.63 (d; 2J =
6.0Hz; 1H; CH), 7.28 (br.s; 1H; NH), 7.40 (m; 2H; CHarom), 7.44 (m; 3H; CHarom). 13C–NMR: (100 MHz, CDCl3/5% TFA): δ (ppm) = 21.7 (1C; CH3), 57.9 (1C; CH),
127.6 (2C; 2 × CHarom), 129.9 (2C; 2 × CHarom), 130.3 (1C; CHarom), 133.2 (1C; Cq),
170.3 (1C; C=O), 176.4 (1C; C=O).
189
Experiment 36
Acetyl Glycyl-Glycine (72e) (SG-153)
NH
OHN
O
CO2H
C6H10N2O4Mol. Wt.: 174.15 g/mol
General procedure (D) was followed, with slight variation, using 1-
aminocyclohexane carboxylic acid (0.7 g, 5.0 mmol). The solution was not refluxed,
instead it was heated gently to 120oC until all the acid had dissolved and was then
stirred at room temperature for 3 nights. Following distillation, no purification was
necessary as the 1H-NMR showed this to be pure product. The yield was found to be
0.8 g (4.81 mmol; 96%). The product was a pale yellow powder.
1H–NMR: (400 MHz, CDCl3/5% TFA): δ (ppm) = 2.24 (s; 3H; CH3), 4.21 (t; 3J =
5.0Hz; 4H; 2 × CH2), 7.47 (br.s; 1H; NH), 7.78 (br.s; 1H; NH). 13C–NMR: (100 MHz, CDCl3/5% TFA): δ (ppm) = 21.4 (1C; CH3), 41.6 (1C; CH2),
43.5 (1C; CH2), 171.6 (1C; C=O), 175.2 (2C; 2 × C=O).
CAS No.: 5687-48-9
Experiment 37
E- and Z-2-methyl-1-methylsulfanylmethylene-3-oxo-2,3-dihydro-1H-isoindole-
5-carboxylic acid methyl ester (E-, Z-74) (SG-20)
N
O
CH3H3CO2C
SCH3
N
O
CH3H3CO2C
SCH3
C13H13NO3SMol. Wt.: 263.31 g/mol
190
General procedure (A) was followed with a few modifications, using 0.2 g (1.1
mmol) of N-methyl trimellitic acid imide methyl ester (instead of NMP). The
solution was then degassed by N2 and 1 ml of dimethylsulfide added. Due to the
volatility of the reagent another 1 ml of dimethylsulfide was added after 4.5 hr. After
24 hr the TLC showed the product was formed. The solution gradually turned pale
yellow in colour. The crude yield was found to be 0.4 g. Following column
chromatography it was assumed from the TLC that the desired product was collected
in fraction 2. The yield of the pure product was found to be 0.1 g (0.52 mmol, 47%).
The product was bright yellow in colour with a strong odour. Solely the dehydrated
olefinic products were found in the 1H-NMR and dehydration most likely occurred in
the slightly acidic NMR solution upon standing.
Major isomer (E-8): 1H–NMR: (400 MHz, CDCl3) δ (ppm) = 2.57 (s; 3H; SCH3), 3.31 (s; 3H; NCH3),
3.96 (s; 3H; OCH3), 6.09 (s; 1H; CHolef), 8.20 (d; 3J = 8.0Hz; 1H; CHarom), 8.29 (d; 3J
= 8.4Hz; 1H; CHarom), 8.52 (s; 1H; CHarom).
Minor isomer (Z-8): 1H–NMR: (400 MHz, CDCl3): δ (ppm) = 2.53 (s; 3H; SCH3), 3.62 (s; 3H; NCH3),
3.94 (s; 3H; OCH3), 6.26 (s; 1H; CHolef), 8.20 (d; 3J = 8.4Hz; 1H; CHarom), 8.28 (d; 3J
= 8.4Hz; 1H; CHarom), 8.49 (s; 1H; CHarom).
Mass spec: [MS + H]: 289 m/z; expected 288 m/z
Melting point: 156-159oC
191
Experiment 38
Methyl 2-(1-hydroxy-1-((methylthio)methyl)-3-oxoisoindolin-2-yl)acetate (75)
and E- and Z-(1-methylsulfanylmethylene-3-oxo-1,3-dihydroisoindol-2-yl) acetic
acid methyl ester (E-, Z-76) (SG-27)
N
O
H3CS
N
O
SCH3
N
O
SCH3HO
C13H15NO4SMol. Wt.: 281.33 g/mol
C13H13NO3SMol. Wt.: 263.31 g/mol
CO2CH3 CO2CH3CO2CH3
General procedure (A) was followed with a few modifications, using 0.2 g (1.1
mmol) of phthaloyl glycine methyl ester (instead of NMP). The solution was then
degassed by N2 and 1 ml of dimethylsulfide added. After 4.5 hr the TLC showed the
product was formed. The solution remained colourless. The crude yield was 0.3 g
(1.21 mmol). Following column chromatography it was assumed from the TLC that
the desired product was collected in fractions 2 and 3. The yield was found to be 0.2
g (0.81 mmol, 74%). The product was a light beige viscous oil with a strong odour.
The desired photoproduct and its corresponding dehydrated olefinics were found in
the 1H-NMR. Dehydration most likely occurred in the slightly acidic NMR solution
upon standing.
Main product (75): 1H–NMR: (400 MHz, CDCl3): δ (ppm) = 1.86 (s; 3H; SCH3), 3.02 (d; 2J = 15.7Hz;
1H; CH2S), 3.05 (d; 2J = 15.7Hz; 1H; CH2S), 3.67 (s; 3H; OCH3), 3.93 (d; 2J =
17.7Hz; 1H; NCH2), 4.17 (br.s; 1H; OH), 4.46 (d; 2J = 17.7Hz; 1H; NCH2), 7.43
(ddd; 3J = 7.3 + 7.6Hz; 4J = 1.0Hz; 1H; CHarom), 7.52 (ddd; 3J = 7.3 + 7.6Hz; 4J =
1.0Hz; 1H; CHarom), 7.60 (dd; 3J = 7.6Hz; 4J = 1.0Hz; 1H; CHarom), 7.69 (dd; 3J =
7.3Hz; 4J = 1.0Hz; 1H; CHarom).
Major isomer (Z-76): 1H–NMR: (400 MHz, CDCl3): δ (ppm) = 2.43 (s; 3H; SCH3), 3.67 (s; 3H; OCH3)
4.49 (s; 2H; NCH2), 5.78 (s; 1H; CHolef), 7.41 (ddd; 3J = 7.6 + 7.8Hz; 4J = 1.0Hz;
192
1H; CHarom), 7.56 (ddd; 3J = 7.6 + 7.8Hz; 4J = 1.0Hz; 1H; CHarom), 7.79 (dd; 3J =
7.6Hz; 4J = 1.0Hz; 1H; CHarom), 8.11 (dd; 3J = 7.8Hz; 4J = 1.0Hz; 1H; CHarom).
Minor isomer (E-76): 1H–NMR: (400 MHz, CDCl3): δ (ppm) = 2.38 (s; 3H; SCH3), 3.70 (s; 3H; OCH3)
4.83 (s; 2H; NCH2), 6.10 (s; 1H; CHolef), 7.36 (ddd; 3J = 7.6Hz; 4J = 1.0Hz; 1H;
CHarom), 7.48 (ddd; 3J = 7.6Hz; 4J = 1.0Hz; 1H; CHarom), 7.51 (dd; 3J = 7.6Hz; 4J =
1.0Hz; 1H; CHarom), 7.74 (dd; 3J = 7.6Hz; 4J = 1.0Hz; 1H; CHarom).
Mass spec: [MS + H]: 264 m/z; expected 263 m/z
Experiment 39
3-Hydroxy-3-(methoxyethyl)-2-methylisoindolin-1-one (77) (SG-7)
N
O
CH3
HOOCH3
C12H15NO3Mol. Wt.: 221.25 g/mol
General procedure (A) was followed using NMP (0.2 g, 1.50 mmol), 3-
methoxypropionic acid (0.5 g, 4.50 mmol) and K2CO3 (0.3 g, 2.26 mmol). After 16
hr the TLC showed a product was formed. The solution was clear and a yellow-green
in colour. The crude yield was found to be 0.2 g (0.76 mmol). Following column
chromatography it was assumed from the TLC that the desired product was collected
in fractions 4 and 5. The 1H-NMR obtained confirmed this and the yield was found
to be 0.03 g (0.12 mmol, 8%). The product was colourless and crystalline. From the
crude 1H-NMR a conversion of just 33% was calculated. Thus, the % yield based on
conversion was determined as 24%.
1H–NMR: (400 MHz, CDCl3): δ (ppm) = 2.25 (m; 1H; CH2), 2.44 (m; 1H; CH2),
2.84 (s; 3H; NCH3), 3.10 (t; 3J = 6.4Hz; 2H; CH2), 3.16 (s; 3H; OCH3) 4.14 (br.s;
193
1H; OH), 7.41 (ddd; 3J = 7.6Hz; 4J = 2.0Hz; 1H; CHarom), 7.54 (ddd; 3J = 6.0Hz; 4J =
0.8Hz; 2H; CHarom), 7.58 (dd; 3J = 7.2Hz; 4J = 0.8Hz; 1H; CHarom). 13C–NMR: (100 MHz, CDCl3): δ (ppm) = 23.9 (1C; NCH3), 36.0 (1C; CH2), 59.2
(1C; CH2O), 68.3 (1C; OCH3), 89.8 (1C; C-OH), 122.3 (1C; CHarom), 123.5 (1C;
CHarom), 129.9 (1C; CHarom), 131.3 (1C; Cq), 132.5 (1C; CHarom), 146.9 (1C; Cq),
167.3 (1C; C=O).
Literature reference No.: [38a]
CAS No.: 261730-87-4
Experiment 40
N-((1-hydroxy-2-methyl-3-oxoisoindolin-1-yl)methyl)acetamide (78a) (SG-107)
N
O
CH3
HOHN O
C12H14N2O3Mol. Wt.: 234.25 g/mol
General procedure (A) was followed using NMP (0.2 g, 1.51 mmol), N-acetyl-
glycine (0.5 g, 4.51 mmol) and K2CO3 (0.3 g, 2.24 mmol). After 3.5 hr the TLC
showed the product was formed. The solution was clear and a pale yellow in colour
at this point. The crude material was found to be 0.02 g. The aqueous layer from the
extraction was then extracted with DCM (3 × 50 ml). The solvent was evaporated
and a brown oily solid visible. This was proved to be the desired product by 1H-
NMR and the yield was found to be 0.1 g (0.29 mmol, 19%) although this was not
entirely pure. There was not enough product available to obtain a 13C NMR.
1H–NMR: (400 MHz, CDCl3): δ (ppm) = 1.76 (s; 3H; CH3), 2.79 (s; 3H; NCH3),
3.65 (dd; 2J = 14.4Hz; 3J = 6.4Hz; 1H; CH2), 3.80 (dd; 2J = 14.4Hz; 3J = 6.4Hz; 1H;
CH2), 5.60 (br.s; 1H; OH), 6.11 (br.t; 3J = 6.0Hz; 1H; NH), 7.35 (ddd; 3J = 8.0Hz; 4J
= 1.6Hz; 1H; CHarom), 7.42 (d; 3J = 7.6Hz; 1H; CHarom), 7.49 (m; 2H; CHarom).
194
CAS No.: 1238840-19-1
Experiment 41
N-(2-(1-hydroxy-2-methyl-3-oxoisoindolin-1-yl)propan-2-yl)acetamide (78b)
(SG-139)
N
O
HO
CH3
NH
O
C14H18N2O3Mol. Wt.: 262.3 g/mol
General procedure (A) was followed, with the slight variation of halving all amounts
used and performing the irradiation in a 50 ml Schlenk flask, using NMP (0.1 g, 0.76
mmol), 72c (0.3 g, 2.26 mmol) and K2CO3 (0.2 g, 1.15 mmol). After 4.5 hr the TLC
showed the product was formed. The solution was clear and a pale yellow in colour
at this point. The product was found to be pale yellow, oily crystals and the 1H-NMR
showed this was the pure product. The yield was found to be 0.2 g (0.63 mmol,
83%).
1H–NMR: (400 MHz, C2D6CO): δ (ppm) = 1.00 (s; 3H; CH3), 1.53 (s; 3H; CH3),
2.09 (s; 3H; CH3), 3.00 (s; 3H; NCH3), 7.50 (ddd; 3J = 7.2Hz; 4J = 1.2Hz; 1H;
CHarom), 7.58 (ddd; 3J = 7.6Hz; 4J = 1.2Hz; 1H; CHarom), 7.61 (d; 3J = 7.2Hz; 1H;
CHarom), 7.65 (dd; 3J = 7.2Hz; 4J = 0.8Hz; 1H; CHarom), 7.74 (br.s; 1H; OH). 13C–NMR: (100 MHz, C2D6CO): δ (ppm) = 23.3 (1C; CH3), 23.8 (1C; CH3), 25.0
(1C; CH3), 26.1 (1C; NCH3), 62.8 (1C; Cq), 95.9 (1C; COH), 123.1 (1C; CHarom),
124.3 (1C; CHarom), 129.9 (1C; CHarom), 132.2 (1C; CHarom), 133.3 (1C; Cqarom),
148.4 (1C; Cqarom), 168.2 (1C; C=O), 174.9 (1C; C=O).
Mass spec: [MS + Na]: 285 m/z; expected 262 m/z
Melting point: 135-138oC
195
CAS No.: 1238840-34-0
Experiment 42
N-((S)-1-(Like and Unlike-1-hydroxy-2-methyl-3-oxoisoindolin-1-yl)-2-
methylpropyl)acetamide (78c) (SG-68)
N CH3
O
HONH
O
C15H20N2O3Mol. Wt.: 276.33 g/mol
N CH3
O
HONH
O
General procedure (A) was followed using NMP (0.2 g, 1.51 mmol), acetyl-valine
(0.7 g, 4.51 mmol) and K2CO3 (0.3 g, 2.25 mmol). After 3.5 hr the TLC showed the
product was formed. The solution was clear and a pale yellow in colour at this point.
The crude material was found to be 0.2 g. This was washed several times with
hexane and the solvent removed. The 1H-NMR obtained confirmed that both isomers
were present in a ratio of 75:25 and the yield was found to be 0.2 g (0.79 mmol,
52%). The product was an off-white powdery solid. These isomers were not isolated.
1H–NMR: (400 MHz, C2D6CO): δ (ppm) = 0.30 (d; 3J = 6.8Hz; 3H; CH3), 0.91 (d; 3J
= 6.8Hz; 3H; CH3), 1.72 (m; 1H; CH), 2.11 (s; 3H; C(O)CH3), 3.00 (s; 3H; NCH3),
4.53 (dd; 3J = 8.8Hz; 4J = 3.2Hz; 1H; CHasym), 6.09 (s; 1H; OH), 7.23 (br.d; 3J =
8.0Hz; 1H; NH), 7.51 (ddd; 3J = 7.2Hz; 4J = 1.2Hz; 1H; CHarom), 7.56 (ddd; 3J =
7.2Hz; 4J = 1.2Hz; 1H; CHarom), 7.66 (m; 1H; CHarom), 7.74 (m; 1H; CHarom). 13C–NMR: (100 MHz, C2D6CO): δ (ppm) = 17.45 (1C; CH3), 22.30 (1C; CH3),
22.72 (1C; CH), 24.27 (1C; C(O)CH3), 28.30 (1C; NCH3), 58.57 (1C; CHasym), 91.93
(1C; COH), 122.81 (1C; CHarom), 124.49 (1C; CHarom), 129.78 (1C; CHarom), 132.00
(1C; CHarom), 134.74 (1C; Cq), 147.37 (1C; Cq), 167.09 (1C; C=O), 172.02 (1C;
C=O).
Mass spec: [MS + Na]: 299 m/z; expected 276 m/z
196
Melting point: 110-114oC
Experiment 43
N-((S)-1-(Like and Unlike-1-hydroxy-2-methyl-3-oxoisoindolin-1-yl)-2-
methylpropyl)acetamide (78c) (SG-181)
N CH3
O
HONH
O
C15H20N2O3Mol. Wt.: 276.33 g/mol
N CH3
O
HONH
O
General procedure (A1) was followed using NMP (0.24 g, 1.50 mmol), acetyl-valine
(0.72 g, 4.50 mmol) and K2CO3 (0.31 g, 2.25 mmol). After 3.5 hr the TLC showed
the product was formed. The solution was clear and a pale yellow in colour at this
point. The crude material was found to be 0.30 g. The 1H-NMR obtained confirmed
that both isomers were present in a ratio of 62:38. Column chromatography was
performed and one isomer isolated in fractions 13-35 which had a combined yield of
0.13 g (0.48 mmol, 32%). The product was an off-white powdery solid.
For 1H-NMR data see experiment 42.
Experiment 44
N-(1-(1-hydroxy-2-methyl-3-oxoisoindolin-1-yl)-3-methylbutyl)acetamide (78d)
(SG-60)
N
O
CH3
HONH
O
C16H22N2O3Mol. Wt.: 290.36 g/mol
197
General procedure (A) was followed using NMP (0.24 g, 1.50 mmol), acetyl-leucine
(0.78 g, 4.50 mmol) and K2CO3 (0.31 g, 2.25 mmol). After 3 hr the TLC showed the
product was formed. The solution was clear and a pale yellow in colour at this point.
The crude material was found to be 0.42 g and the 1H-NMR showed that both
isomers had been formed in a ratio of 38:62. Following column chromatography it
was assumed from the TLC, that the desired product was collected in fraction 9. The 1H-NMR obtained confirmed this to be a single isomer which had a yield of 0.11 g
(0.39 mmol, 26%). The product was a colourless foam.
1H–NMR: (400 MHz, C2D6CO): δ (ppm) = 0.95 (q; 3J = 6.4Hz; 4J = 2.0Hz; 6H; 2 ×
CH3), 1.59-1.76 (m; 3H; CH2 + CH), 1.78 (s; 3H; CH3), 3.03 (s; 3H; NCH3), 4.70
(ddd; 3J = 11.6Hz; 4J = 2.0Hz; 1H; CH), 5.73 (s; 1H; OH), 6.59 (br.d; 3J = 8.8Hz;
1H; NH), 7.54 (ddd; 3J = 7.2Hz; 4J = 1.2Hz; 1H; CHarom), 7.62 (ddd; 3J = 7.6Hz; 4J =
1.2Hz; 1H; CHarom), 7.68 (m; 2H; CHarom). 13C–NMR: (100 MHz, C2D6CO): δ (ppm) = 21.7 (1C; CH), 22.7 (1C; NCH3), 24.1
(1C; CH3), 24.2 (1C; CH3), 25.9 (1C; CH3), 39.8 (1C; CH2), 52.1 (1C; CH), 92.4
(1C; COH), 123.1 (1C; CHarom), 124.2 (1C; CHarom), 130.1 (1C; CHarom), 132.0 (1C;
CHarom), 134.2 (1C; Cq), 146.3 (1C; Cq), 166.9 (1C; C=O), 171.0 (1C; C=O).
Mass spec: [MS + Na]: 313 m/z; expected 290 m/z
Melting point: 105-108oC
Experiment 45
N-(1-(1-hydroxy-2-methyl-3-oxoisoindolin-1-yl)-3-methylbutyl)acetamide (78d)
(SG-177)
N
O
CH3
HONH
O
C16H22N2O3Mol. Wt.: 290.36 g/mol
198
General procedure (A1) was followed using NMP (0.24 g, 1.51 mmol), acetyl-
leucine (0.78 g, 4.50 mmol) and K2CO3 (0.31 g, 2.26 mmol). After 4 hr the TLC
showed the product was formed. The solution was clear and a pale yellow in colour
at this point. The crude material was found to be 0.32 g. The 1H-NMR showed that
both isomers of the product had formed in a ratio of 39:61. Following column
chromatography, one isomer was isolated in fraction 25. The 1H-NMR obtained
confirmed this and the yield was found to be 0.16 g (0.54 mmol, 36%). The product
was a colourless foam.
For 1H-NMR data see experiment 44.
Experiment 46
N-((1S,2S) and (1S,2R)-1-((R) and (S)-1-hydroxy-2-methyl-3-oxoisoindolin-1-yl)-
2-methylbutyl)acetamide (78e) (SG-69)
N
O
CH3
HONH O
C16H22N2O3Mol. Wt.: 290.36 g/mol
N
O
CH3
HONH O
N
O
CH3
HONH O
N
O
CH3
HONH O
General procedure (A) was followed using NMP (0.2 g, 1.50 mmol), acetyl-
isoleucine (0.8 g, 4.51 mmol) and K2CO3 (0.3 g, 2.25 mmol). After 3 hr the TLC
showed the product was formed. The solution was clear and a pale yellow in colour
at this point. The crude material was found to be 0.4 g. This was washed several
times with hexane and the solvent removed. The 1H-NMR obtained confirmed that
four diastereoisomers were formed in a ratio of 32:15:34:19. The yield was found to
be 0.3 g (1.17 mmol, 78%). The product was an off-white powder with some yellow
oily spots. These isomers were not isolated, however data for some selected peaks is
listed.
199
1H–NMR: (400 MHz, C2D6CO): δ (ppm) =
Selected peaks for NH:
6.43 (d; 3J = 6.8Hz; 1H; NH), 6.49 (d; 3J = 4.8Hz; 1H; NH), 6.82 (d; 3J = 10.4Hz;
1H; NH), 6.92 (d; 3J = 10.4Hz; 1H; NH).
Selected peaks for CH(NH):
4.39 (dd; 3J = 10.4Hz; 3J = 4.0Hz; 1H; CH), 4.48 (dd; 3J = 9.6Hz; 3J = 4.0Hz; 1H;
CH), 4.57 (dd; 3J = 10.4Hz; 3J = 4.0Hz; 1H; CH), 4.65 (dd; 3J = 10.0Hz; 3J = 2.4Hz;
1H; CH).
Mass spec: [MS + Na]: 313 m/z; expected 290 m/z
Melting point: 115-117oC
Experiment 47
N-((S)-1-(Like and Unlike-1-hydroxy-2-methyl-3-oxoisoindolin-1-yl)-2,2-
dimethylpropyl)acetamide (78f) (SG-127)
N
O
HO
CH3
NH
O
C16H22N2O3Mol. Wt.: 290.36 g/mol
N
O
HO
CH3
NH
O
General procedure (A) was followed, with slight variation of amounts used but not
the ratio, using NMP (0.1 g, 0.66 mmol), 72a (0.3 g, 1.95 mmol) and K2CO3 (0.1 g,
0.98 mmol). After 8.5 hr the TLC showed the product was formed. The solution was
clear and a pale yellow in colour at this point. The crude material was found to be 0.1
g. The 1H-NMR showed both isomers had been formed in a ratio of 74:26. There
were also a few impurities present so the product was washed with acetone several
times. A colourless powder was obtained and a second 1H-NMR showed this to be
only one isomer of the pure product. The yield was found to be 0.01 g (0.04 mmol,
6%).
200
1H–NMR: (400 MHz, C2D6CO): δ (ppm) = 0.67 (s; 9H; 3 × CH3), 2.14 (s; 3H; CH3),
3.00 (s; 3H; NCH3), 4.55 (d; 3J = 9.2Hz; 1H; CH), 5.91 (br.s; 1H; OH), 7.45 (br.d; 3J
= 8.8Hz; 1H; NH), 7.50-7.57 (br.m; 2H; CHarom), 7.67 (m; 1H; CHarom), 7.86 (m; 1H;
CHarom). 13C–NMR: (100 MHz, C2D6CO): δ (ppm) = 24.8 (1C; NCH3), 28.3 (3C; 3 × CH3),
35.0 (1C; Cq), 38.3 (1C; CH3), 60.4 (1C; CH), 91.7 (1C; COH), 123.4 (1C; CHarom),
125.0 (1C; CHarom), 130.3 (1C; CHarom), 132.3 (1C; CHarom), 134.0 (1C; Cqarom),
148.8 (1C; Cqarom), 167.8 (1C; C=O), 170.9 (1C; C=O).
Mass spec: [MS + Na]: 313 m/z; expected 290 m/z
Melting point: 143-147oC
Experiment 48
N-(Like and Unlike-1-hydroxy-2-methyl-3-oxoisoindolin-1-
yl)(phenyl)methyl)acetamide (78g) (SG-152)
N
O
HO
CH3
NH
O
C18H18N2O3Mol. Wt.: 310.35 g/mol
N
O
HO
CH3
NH
O
General procedure (A) was followed, with the slight variation of halving all amounts
used and using a 50 ml reaction flask, using NMP (0.1 g, 0.75 mmol), 72d (0.4 g,
2.18 mmol) and K2CO3 (0.2 g, 1.12 mmol). After 2 hr the TLC showed the product
was formed. The solution was clear and a pale yellow in colour at this point. The
product was found to be a colourless/yellow solid and the 1H-NMR showed that both
isomers had been formed. The ratio was determined to be 54:46 so almost no
preference was shown for either isomer. The yield was found to be 0.2 g (0.78 mmol,
104%), but this obviously includes a few impurities. The isomers were not isolated
and the peaks could not be assigned from the 1H-NMR.
201
Melting point: 189-191oC
Experiment 49
tert-butyl (1-hydroxy-2-methyl-3-oxoisoindolin-1-yl)methylcarbamate (78h)
(SG-73)
N
O
HONH OCH3
O
C15H20N2O4Mol. Wt.: 292.33 g/mol
General procedure (A) was followed using NMP (0.2 g, 1.52 mmol), N-(tert-
butoxycarbonyl)-glycine (0.8 g, 4.51 mmol) and K2CO3 (0.3 g, 2.25 mmol). After 1
hr the TLC showed the product was formed. The solution remained clear and
colourless. During work-up, a precipitate was formed. This was filtered and found to
be a colourless powder. The 1H-NMR showed that this was the pure product with a
yield of 0.3 g (0.90 mmol; 59%). Work-up was continued as usual and the crude
material was found to be 0.2 g. This was washed several times with acetone and the
solvent removed. The 1H-NMR obtained confirmed that this was the pure product
and the yield was found to be 0.1 g (0.22 mmol, 15%). The product was a colourless
powder. Collective yield = 74%.
1H–NMR: (400 MHz, C2D6CO): δ (ppm) = 1.21 (s; 9H; 3 × CH3), 2.97 (s; 3H;
NCH3), 3.66 (dd; 2J = 14.4Hz; 3J = 6.4Hz; 1H; CH2), 3.84 (dd; 2J = 14.4Hz; 3J =
6.8Hz; 1H; CH2), 5.46 (br.s; 1H; OH), 5.87 (br.s; 1H; NH), 7.47 (t; 3J = 7.2Hz; 1H;
CHarom), 7.55 (t; 3J = 7.6Hz; 1H; CHarom), 7.62 (t; 3J = 8.4Hz; 2H; CHarom). 13C–NMR: (100 MHz, C2D6CO): δ (ppm) = 23.5 (1C; NCH3), 28.2 (3C; 3 × CH3),
44.1 (1C; CH2), 78.4 (1C; Cq), 90.2 (1C; COH), 122.3 (1C; CHarom), 123.9 (1C;
CHarom), 129.6 (1C; CHarom), 131.8 (1C; CHarom), 147.0 (1C; Cqarom), 156.2 (1C;
Cqarom), 167.2 (1C; C=O), 170.1 (1C; C=O).
Mass spec: [MS + Na]: 315 m/z; expected 292 m/z
202
Melting point: 108-112oC
CAS No.: 1238840-25-9
Experiment 50
tert-butyl (S)-1-(Like and Unlike- 1-hydroxy-2-methyl-3-oxoisoindolin-1-
yl)ethylcarbamate (78i) (SG-63)
N
O
CH3
HONH O
O
C16H22N2O4Mol. Wt.: 306.36 g/mol
N
O
CH3
HONH O
O
General procedure (A) was followed using NMP (0.2 g, 1.50 mmol), N-(tert-
butoxycarbonyl)-L-alanine (0.9 g, 4.50 mmol) and K2CO3 (0.3 g, 2.25 mmol). After
2 hr the TLC showed the product was formed. The solution was clear and a pale
yellow in colour at this point. The crude material was found to be 0.5 g. The 1H-
NMR showed both isomers of the product had been formed in a ratio of 69:31,
however an assignment could not be made. Following column chromatography, it
was found that the isomers could not be separated and were both collected in
fractions 3-7. The 1H-NMR obtained showed this and the yield was found to be 0.30
g (0.97 mmol, 65%). The product was an off-white solid.
Major Isomer: 1H–NMR: (400 MHz, C2D6CO): δ (ppm) = 1.37 (s; 6H; 2 × CH3), 1.41 (s; 3H; CH3),
1.44 (d; 3J = 6.8Hz; 3H; CH3), 3.03 (s; 3H; NCH3), 4.40 (m; 1H; CH), 5.52 (br.d; 3J
= 8.0Hz; 1H; NH), 5.67 (br.s; 1H; OH), 7.54 (ddd; 3J = 7.2Hz; 4J = 1.2Hz; 1H;
CHarom), 7.60 (ddd; 3J = 7.2Hz; 4J = 1.2Hz; 1H; CHarom), 7.68 (m; 2H; CHarom). 13C–NMR: (100 MHz, C2D6CO): δ (ppm) = 16.67 (1C; CH3), 24.14 (1C; NCH3),
28.45 (3C; 3 × CH3), 50.65 (1C; CH), 79.13 (1C; Cq), 92.47 (1C; C-OH), 123.13
203
(1C; CHarom), 124.33 (1C; CHarom), 130.09 (1C; CHarom), 132.03 (1C; CHarom), 134.03
(1C; Cqarom), 145.79 (1C; Cqarom), 156.53 (1C; C=O), 167.09 (1C; C=O).
Experiment 51
tert-butyl (S)-1-(Like and Unlike- 1-hydroxy-2-methyl-3-oxoisoindolin-1-
yl)ethylcarbamate (78i) (SG-184)
N
O
CH3
HONH O
O
C16H22N2O4Mol. Wt.: 306.36 g/mol
N
O
CH3
HONH O
O
General procedure (A1) was followed using NMP (0.24 g, 1.50 mmol), N-(tert-
butoxycarbonyl)-L-alanine (0.85 g, 4.51 mmol) and K2CO3 (0.31 g, 2.26 mmol).
After 4 hr the TLC showed the product was formed. The crude material was found to
be 0.53 g. The 1H-NMR showed both isomers of the product had been formed,
however the ratio could not be determined and an assignment could not be made.
Following column chromatography, it was found that the isomers could not be
separated and were both collected in fractions 2-3. The 1H-NMR obtained showed
this and the yield was found to be 0.37 g (1.21 mmol; 81%). The product was an off-
white solid.
For 1H-NMR data see experiment 50.
204
Experiment 52
tert-butyl (S)-1-(Like and Unlike-1-hydroxy-2-methyl-3-oxoisoindolin-1-yl)-2-
phenylethylcarbamate (78j) (SG-64)
N
O
CH3
HONH O
O
C22H26N2O4Mol. Wt.: 382.45 g/mol
N
O
CH3
HONH O
O
General procedure (A) was followed using NMP (0.2 g, 1.50 mmol), N-(tert-
butoxycarbonyl)-L-phenylalanine (1.2 g, 4.50 mmol) and K2CO3 (0.3 g, 2.26 mmol).
After 3 hr the TLC showed the product was formed. The solution was clear and a
pale yellow in colour at this point. The crude material was found to be 0.6 g. From
the 1H-NMR it was evident that both isomers of the product had been formed. The
ratio was calculated from the crude 1H-NMR to be 32:68, although it was not
possible to distinguish between the two. Following column chromatography it was
assumed from the TLC, that one isomer, a colourless solid, was collected in fraction
4 (minor isomer) and the other, an off-white solid, in fraction 8 (major isomer). The 1H-NMRs obtained confirmed this and the yields were found to be 0.04 g (0.10
mmol, 7%) and 0.1 g (0.29 mmol, 19%) respectively.
Major Isomer: 1H–NMR: (400 MHz, C2D6CO): δ (ppm) = 1.20 (s; 9H; 3 × CH3), 2.98 (dd; 2J =
11.2Hz; 3J = 1.6Hz; 1H; CH2), 3.06 (s; 3H; NCH3), 3.63 (dd; 2J = 14.0Hz; 3J =
2.0Hz; 1H; CH2), 4.47 (ddd; 3J = 10.0Hz; 4J = 2.4Hz; 1H; CH), 5.61 (br.d; 3J =
8.4Hz; 1H; NH), 5.73 (br.s; 1H; OH), 7.20-7.38 (m; 5H; CHarom), 7.57 (ddd; 3J =
7.2Hz; 4J = 0.8Hz; 1H; CHarom), 7.64 (ddd; 3J = 7.6Hz; 4J = 1.2Hz; 1H; CHarom), 7.70
(d; 3J = 7.2Hz; 1H; CHarom), 7.81 (d; 3J = 7.6Hz; 1H; CHarom). 13C–NMR: (100 MHz, C2D6CO): δ (ppm) = 23.9 (1C; NCH3), 28.3 (3C; 3 × CH3),
36.6 (1C; CH2), 56.8 (1C; CH), 78.3 (1C; Cq), 92.0 (1C; C-OH), 122.6 (1C; CHarom),
124.7 (1C; CHarom), 126.4 (1C; CHarom), 128.5 (2C; CHarom), 129.7 (1C; CHarom),
205
129.8 (2C; CHarom), 131.7 (1C; CHarom), 134.2 (1C; Cqarom), 140.4 (1C; Cqarom),
145.9 (1C; Cqarom), 156.2 (1C; C=O), 166.7 (1C; C=O).
Minor Isomer: 1H–NMR: (400 MHz, C2D6CO): δ (ppm) = 1.21 (s; 9H; 3 × CH3), 2.50 (dd; 2J =
11.2Hz; 3J = 5.6Hz; 1H; CH2) 3.07 (dd; 2J = 11.2Hz; 3J = 5.6Hz; 1H; CH2), 3.15 (s;
3H; NCH3), 4.58 (t; 3J = 9.6Hz; 1H; CH), 5.79 (br.s; 1H; OH), 6.36 (br.d; 3J =
8.4Hz; 1H; NH), 7.21 (m; 1H; CHarom), 7.30 (m; 4H; CHarom), 7.53 (ddd; 3J = 7.2Hz; 4J = 0.8Hz; 1H; CHarom), 7.60 (t; 3J = 7.2Hz; 1H; CHarom), 7.68 (d; 3J = 7.2Hz; 1H;
CHarom), 7.75 (d; 3J = 7.2Hz; 1H; CHarom). 13C–NMR: (100 MHz, C2D6CO): δ (ppm) = 24.9 (1C; NCH3), 28.3 (3C; 3 × CH3),
36.2 (1C; CH2), 58.2 (1C; CH), 79.2 (1C; Cq), 92.5 (1C; C-OH), 122.8 (1C; CHarom),
124.4 (1C; CHarom), 126.9 (1C; CHarom), 129.0 (2C; CHarom), 129.9 (1C; CHarom),
130.0 (2C; CHarom), 132.2 (1C; CHarom), 133.2 (1C; Cqarom), 139.8 (1C; Cqarom),
143.8 (1C; Cqarom), 157.2 (1C; C=O), 169.9 (1C; C=O).
Experiment 53
tert-butyl (S)-1-(Like and Unlike-1-hydroxy-2-methyl-3-oxoisoindolin-1-yl)-2-
phenylethylcarbamate (78j) (SG-185)
N
O
CH3
HONH O
O
C22H26N2O4Mol. Wt.: 382.45 g/mol
N
O
CH3
HONH O
O
General procedure (A1) was followed using NMP (0.24 g, 1.51 mmol), N-(tert-
butoxycarbonyl)-L-phenylalanine (1.19 g, 4.50 mmol) and K2CO3 (0.31 g, 2.25
mmol). After 4 hr the TLC showed the product was formed. The crude material was
found to be 0.72 g. From the 1H-NMR it was evident that both isomers of the product
had been formed. The ratio was calculated from the crude 1H-NMR to be 35:65,
although it was not possible to distinguish between the two. Following column
206
chromatography, the isomers could not be separated and the resulting 1H-NMR was
almost identical to the crude.
For 1H-NMR data see experiment 52.
Experiment 54
N-(1-(1-hydroxy-2-methyl-3-oxoisoindolin-1-yl)cyclohexyl)acetamide (78k) (SG-
140)
N
O
HO
CH3
NH
O
C17H22N2O3Mol. Wt.: 302.37 g/mol
General procedure (A) was followed, with the slight variation of halving all amounts
used and using a 50 ml Schlenk flask, using NMP (0.1 g, 0.75 mmol), 72b (0.4 g,
2.27 mmol) and K2CO3 (0.2 g, 1.12 mmol). After 4 hr the TLC showed the product
was formed. The solution was clear and a pale yellow in colour at this point. The
crude material was found to be 0.2 g. The 1H-NMR showed a few impurities were
present so the product was washed with acetone several times. The impurities did not
dissolve in the acetone so the product was removed with the solvent and the yield
found to be 0.2 g (0.65 mmol; 87%) when the solvent had evaporated. A second 1H-
NMR confirmed this to be the product.
1H–NMR: (400 MHz, C2D6CO): δ (ppm) = 0.74-1.81 (br.m; 10H; 5 × CH2), 2.19 (s;
3H; CH3), 3.01 (s; 3H; NCH3), 7.36 (br.s; 1H; NH), 7.50 (ddd; 3J = 7.6Hz; 4J =
1.2Hz; 1H; CHarom), 7.58 (ddd; 3J = 7.6Hz; 4J = 1.2Hz; 1H; CHarom), 7.64 (m; 2H;
CHarom), 8.43 (br.s; 1H; OH). 13C–NMR: (100 MHz, C2D6CO): δ (ppm) = 21.6 (2C; 2 × CH2), 23.2 (1C; CH2),
25.7 (2C; 2 × CH2), 26.3 (1C; NCH3), 26.6 (1C; CH3), 48.7 (1C; Cq), 97.2 (1C;
COH), 123.0 (1C; CHarom), 124.7 (1C; CHarom), 129.9 (1C; CHarom), 132.1 (1C;
CHarom), 133.5 (1C; Cqarom), 148.4 (1C; Cqarom), 168.3 (1C; C=O), 175.4 (1C; C=O).
207
Mass spec: [MS + Na]: 325 m/z; expected 302 m/z
Melting point: 160-164oC
CAS No.: 1238840-37-3
Experiment 55
(9H-fluoren-9-yl)methyl (1-hydroxy-2-methyl-3-oxoisoindolin-1-
yl)methylcarbamate (78l) (SG-67)
NO CH3
OHNH O
O
C25H22N2O4Mol. Wt.: 414.45 g/mol
General procedure (A) was followed using NMP (0.2 g, 1.50 mmol), N-(9-
fluorenylmethoxycarbonyl)glycine (1.3 g, 4.50 mmol) and K2CO3 (0.3 g, 2.25
mmol). After 1.5 hr the TLC showed the product was formed. The solution had
changed from clear and a pale yellow in colour to a cloudy, milky solution. When
attempting to extract the solution with DCM, a precipitate was formed. This was
filtered and found to be a colourless powder with a yield of 1.4 g. The filtrate was
then worked up as usual and the crude material found to be 0.3 g. From the 1H-NMR
it was evident that the product had been formed, however an analogue of the acid
starting material was also present. The crude product was washed, in the round
bottom flask, with hexane several times, however the 1H-NMR showed little change.
Following column chromatography it was clear that the product had not been isolated
in any of the fractions collected.
The precipitate was then purified by dissolving it in ethyl acetate (~30 ml) and then
washing the organic layer with saturated NaHCO3 (3 × 30 ml). The aqueous layer
was then extracted with ethyl acetate (3 × 30 ml) and the organic layer washed with
208
NaCl (2 × 20 ml). A precipitate visible throughout the procedure was filtered at this
point. It appeared as a colourless powder and 1H-NMR showed it to be the desired
product with a yield of 0.02 g (0.04 mmol; 3%). Continuing with the purification, the
organic layer was dried over MgSO4 and the solvent evaporated. The product was
seen to be an off-white powder and 1H-NMR confirmed that this was the pure
product, with a yield of 0.1 g (0.24 mmol; 16%).
1H–NMR: (400 MHz, C2D6CO): δ (ppm) = 2.94 (s; 3H; NCH3), 3.59 (dd; 2J =
14.4Hz; 3J = 6.0Hz; 1H; CH2), 3.79 (dd; 2J = 14.4Hz; 3J = 6.8Hz; 1H; CH2), 4.00-
4.14 (br.m; 3H; OCH2 + CH), 6.54 (br.s; 1H; OH), 7.18 (t; 3J = 6.4Hz; 1H; NH), 7.28
(m; 2H; CHarom), 7.39 (t; 3J = 7.2Hz; 2H; CHarom), 7.46 (ddd; 3J = 7.6Hz; 4J = 1.2Hz;
2H; CHarom), 7.53 (d; 3J = 7.6Hz; 1H; CHarom), 7.57 (t; 3J = 7.2Hz; 1H; CHarom), 7.62
(d; 3J = 8.0Hz; 2H; CHarom), 7.84 (d; 3J = 7.6Hz; 2H; CHarom). 13C–NMR: (100 MHz, C2D6CO): δ (ppm) = 23.3 (1C; NCH3), 43.9 (1C; CH), 46.8
(1C; CH2), 66.0 (1C; OCH2), 89.5 (1C; COH), 120.2 (1C; CHarom), 120.2 (1C;
CHarom), 122.0 (1C; CHarom), 123.3 (1C; CHarom), 125.4 (1C; CHarom), 125.5 (1C;
CHarom), 127.3 (1C; CHarom), 127.8 (1C; CHarom), 129.3 (1C; CHarom), 131.6 (1C;
CHarom), 132.6 (1C; CHarom), 140.9 (1C; CHarom), 141.0 (1C; Cq), 144.0 (1C; Cq),
144.1 (1C; Cq), 146.3 (1C; Cq), 147.8 (1C; Cq), 156.4 (1C; Cq), 166.7 (1C; C=O),
169.9 (1C; C=O).
Mass spec: [MS + Na]: 437 m/z; expected 414m/z
Melting point: 185-187oC
CAS No.: 1238840-31-7
209
Experiment 56
(9H-fluoren-9-yl)methyl (1-hydroxy-2-methyl-3-oxoisoindolin-1-
yl)methylcarbamate (78l) (SG-187)
NO CH3
OHNH O
O
C25H22N2O4Mol. Wt.: 414.45 g/mol
General procedure (A1) was followed, with slight variation, using NMP (0.24 g, 1.51
mmol), N-(9-fluorenylmethoxycarbonyl)glycine (0.85 g, 2.88 mmol) and K2CO3
(0.31 g, 2.24 mmol). There was not enough acid available to add the usual 4.50
mmol although it was still used in excess. After 3 hr the TLC showed the product
was formed and the crude material found to be 0.52 g. From the 1H-NMR it was
evident that the product had been formed, however impurities were also present. The
crude product was washed, in the round bottom flask, by adding a small amount of
acetone to dissolve the impurities and then removing the solvent. This was repeated
several times, and the product found to be an off-white powder with a yield of 0.12 g
(0.30 mmol; 20%). The resulting 1H-NMR showed this to be the pure product.
For 1H-NMR data see experiment 55.
210
7.3 Chapter 4: Synthesis of aristolactams using phthalimide
derivatives as precursors
Experiment 57
5,6-dimethoxyisobenzofuran-1(3H)-one (m-meconine) (79a) (SG-236)
OH3CO
H3CO
O
C10H10O4Mol. Wt.: 194.18 g/mol
3,4-dimethoxybenzoic acid (veratric acid) (7.5 g; 41.1 mmol) and paraformaldehyde
(10.0 g) were refluxed in concentrated HCl (250 ml) at 80oC fo ~6 hr. The solution
was cooled to R.T and then a solution of NH4OH poured over ice (250 ml) was
added slowly until the pH changed from 1 to 7. A beige precipitate was visible which
was filtered and washed with H2O. The yield was found to be 3.7 g; (19.1 mmol;
46%). The 1H-NMR confirmed this to be the desired product in its pure state.
SG-243:
The procedure was repeated using 3,4-dimethoxybenzoic acid (veratric acid) (7.51 g;
41.21 mmol) and paraformaldehyde (10.01 g). The product was found to have a yield
of 6.29 g; (32.37 mmol; 79%). The 1H-NMR showed this to be the desired pure
product.
1H–NMR: (400 MHz, CDCl3): δ (ppm) = 3.93 (s; 3H; OCH3), 3.97 (s; 3H; OCH3),
5.21 (s; 2H; CH2), 6.90 (s; 1H; CHarom), 7.29 (s; 1H; CHarom). 13C–NMR: (100 MHz, CDCl3): δ (ppm) = 56.4 (1C; OCH3), 56.5 (1C; OCH3), 69.3
(1C; CH2), 103.5 (1C; CHarom), 106.2 (1C; CHarom), 117.8 (1C; Cq), 141.2 (1C; Cq),
150.5 (1C; Cq), 155.0 (1C; Cq), 171.6 (1C; C=O).
CAS No.: 531-88-4
211
Experiment 58
4,5-dimethoxybenzene-1,2-dioic acid (79b) (SG-62)
CO2H
CO2H
H3CO
H3COC10H10O6
Mol. Wt.: 226.18 g/mol
m-Meconine (4.5 g; 23.5 mmol), 1.1 equivalents of KMnO4 and 2.2 equivalents of a
10% Na2CO3 solution were dissolved by heating, and then stirred at R.T for 1 week.
Ethanol (30 ml) was then added dropwise and the reaction solution allowed to stir for
a further 3 hr. The precipitate formed was discarded after filtering and rinsing with
distilled H2O. The filtrate was then acidified to pH 1 using conc. HCl and left in the
fridge overnight. The colourless precipitate that had formed was filtered and found to
have a yield of 2.4 g (10.7 mmol; 46%). The 1H-NMR showed this was the desired
product. The filtrate was extracted with ethyl acetate (2 × 100 ml), the organic layer
dried over MgSO4, gravity filtered and the solvent evaporated by rotary evaporation.
The crude product was purified by dissolving it in ethyl acetate and washing it with
sat. NaHCO3 in a separating funnel. The bottom aqueous layer was then dropped
onto acidified ice and, when left overnight, a colourless precipitate had formed.
When filtered, this was found to have a yield of 0.94 g (4.16 mmol; 18%). The 1H-
NMR showed this to be the pure product. The second aqueous layer was then
extracted, same as the previous one, and the yield found to be 0.64 g (2.84 mmol;
12%). The product was a colourless powder. [Overall yield = 76%].
1H–NMR: (400 MHz, CDCl3): δ (ppm) = 3.93 (s; 6H; 2 × OCH3), 7.26 (s; 2H;
CHarom), 7.78 (br.s; 2H; OH). 13C–NMR: (100 MHz, CDCl3): δ (ppm) = 55.8 (2C; 2 × OCH3), 111.6 (2C; CHarom),
126.1 (2C; Cq), 149.9 (2C; Cq), 168.4 (2C; 2 × C=O).
CAS No.: 577-68-4
212
Experiment 59
5,6-dimethoxyisobenzofuran-1,3-dione (79c) (SG-65)
O
O
OH3CO
H3CO
C10H8O5Mol. Wt.: 208.17 g/mol
79b (2.0 g; 8.89 mmol) was heated at 140oC for 1 hr while stirring in acetic
anhydride (25 ml). The acetic anhydride was then distilled off and a yellow solid was
formed. The yield was 1.6 g (7.82 mmol; 88%) and the 1H-NMR confirmed this was
the pure product.
1H–NMR: (400 MHz, CDCl3): δ (ppm) = 4.03 (s; 6H; 2 × OCH3), 7.36 (s; 2H;
CHarom). 13C–NMR: (100 MHz, CDCl3): δ (ppm) = 56.9 (2C; 2 × OCH3), 106.1 (2C; CHarom),
124.9 (2C; Cq), 155.8 (2C; Cq), 163.1 (2C; 2 × C=O).
CAS No.: 4821-94-7
Experiment 60
5,6-dimethoxy-2-methylisoindoline-1,3-dione (79d) (SG-66)
N
O
O
CH3
H3CO
H3CO
C11H11NO4Mol. Wt.: 221.21 g/mol
79c (2.0 g; 9.04 mmol) was refluxed at 190oC for 2 hr while stirring in N-
methylformamide (25 ml). This was left overnight to cool and the next day, pale
yellow, fine needles were seen to have formed. These were filtered and washed with
213
a small amount of ethanol. The yield was 1.7 g (7.59 mmol; 84%) and the 1H-NMR
confirmed this was the pure product.
1H–NMR: (400 MHz, CDCl3): δ (ppm) = 3.14 (s; 3H; NCH3), 3.99 (s; 6H; 2 ×
OCH3), 7.30 (s; 2H; CHarom). 13C–NMR: (100 MHz, CDCl3): δ (ppm) = 24.1 (1C; NCH3), 56.8 (2C; 2 × OCH3),
105.4 (2C; CHarom), 125.8 (2C; Cq), 153.8 (2C; Cq), 168.8 (2C; 2 × C=O).
CAS No.: 92288-92-1
Experiment 61
5,6-dimethoxyisoindoline-1,3-dione (79e) (SG-289)
NH
O
O
H3CO
H3CO
C10H9NO4Mol. Wt.: 207.18 g/mol
79c (0.27 g; 1.30 mmol) was refluxed at 190oC for 3 hr while stirring in formamide
(20 ml). This was left overnight to cool and the next day, pale yellow, fine needles
were seen to have formed. These were filtered and washed with a small amount of
ethanol. The yield was 0.20 g (0.94 mmol; 72%) and the 1H-NMR confirmed this
was the pure product.
1H–NMR (400 MHz, CDCl3): δ (ppm) = 3.97 (s; 6H; 2 × OCH3), 7.62 (s; 2H;
CHarom), 10.58 (br.s; 1H; NH). 13C–NMR (100 MHz, CDCl3): δ (ppm) = 55.8 (2C; 2 × OCH3), 104.3 (2C; CHarom),
125.7 (2C; Cq), 153.0 (2C; Cq), 168.8 (2C; C=O).
CAS No.: 4764-20-9
214
7.3.1 General Procedure (E)
Silver trifluoroacetate (20.00 mmol) and the methoxylated phenylacetic acid (20.00
mmol) were stirred while a solution of iodine (20.00 mmol) dissolved in CHCl3 (~60
ml) was added dropwise over a period of ~30 min. After stirring for 2 nights, the
precipitated silver iodide was filtered and washed with CHCl3. The solvent was then
removed by rotary evaporation and the crude product recrystallised from ethanol.
Experiment 62
2-(2-iodo-4,5-dimethoxyphenyl)acetic acid (81a) (SG-203)
H3CO
H3COCO2H
I
C10H11IO4Mol. Wt.: 322.1 g/mol
General procedure (E) was followed using silver trifluoroacetate (4.42 g; 20.01
mmol), 3,4-dimethoxyphenylacetic acid (3.93 g; 20.01 mmol) and iodine (5.08 g;
20.00 mmol). The product was found to be a grey/purple crystalline solid with a
yield of 4.89 g (15.18 mmol; 76%). The 1H-NMR showed this to be the pure product.
SG-258:
General procedure (E) was followed using silver trifluoroacetate (2.21 g; 10.00
mmol), 3,4-dimethoxyphenylacetic acid (1.96 g; 10.01 mmol) and iodine (2.54 g;
10.00 mmol). The product was found to be a brown powdery solid with a yield of
3.12 g (9.67 mmol; 97%). This product was not recrystallised as the 1H-NMR
showed this to be the pure product.
1H–NMR: (400 MHz, CDCl3): δ (ppm) = 3.78 (s; 2H; CH2), 3.85 (s; 6H; 2 × OCH3),
6.80 (s; 1H; CHarom), 7.23 (s; 1H; CHarom). 13C–NMR: (100 MHz, CDCl3): δ (ppm) = 45.49 (1C; CH2), 56.03 (1C; OCH3),
56.21 (1C; OCH3), 88.99 (1C; CI), 113.32 (1C; CHarom), 121.66 (1C; CHarom), 129.30
(1C; Cq), 148.87 (1C; Cq), 149.42 (1C; Cq), 176.83 (1C; C=O).
CAS No.: 35323-09-2
215
Experiment 63
2-(2-iodo-3,4,5-trimethoxyphenyl)acetic acid (81b) (SG-232)
H3CO
H3CO
OCH3
CO2H
I
C11H13IO5Mol. Wt.: 352.12 g/mol
General procedure (E) was followed using silver trifluoroacetate (4.42 g; 20.00
mmol), 3,4,5-trimethoxyphenylacetic acid (4.53 g; 20.00 mmol) and iodine (5.08 g;
20.00 mmol). This reaction was only stirred for 1 night. The product was found to be
an off-white powder with a yield of 3.22 g (9.14 mmol; 46%). The 1H-NMR showed
this to be the pure product.
SG-261:
General procedure (E) was followed using silver trifluoroacetate (4.42 g; 20.00
mmol), 3,4,5-trimethoxyphenylacetic acid (4.52 g; 20.00 mmol) and iodine (5.08 g;
20.00 mmol). This reaction was only stirred for 1 night. The product was found to be
an off-white powder with a yield of 4.40 g (12.50 mmol; 63%). The 1H-NMR
showed this to be the pure product.
1H–NMR: (400 MHz, CDCl3): δ (ppm) = 3.85 (s; 3H; OCH3), 3.86 (s; 2H; CH2),
3.86 (s; 3H; OCH3), 3.87 (s; 3H; OCH3), 6.71 (s; 1H; CHarom). 13C–NMR: (100 MHz, CDCl3): δ (ppm) = 46.2 (1C; CH2), 56.2 (1C; OCH3), 60.9
(1C; OCH3), 61.1 (1C; OCH3), 89.2 (1C; CI), 110.2 (1C; CHarom), 132.5 (1C; Cq),
141.4 (1C; Cq), 153.4 (1C; Cq), 153.7 (1C; Cq), 176.6 (1C; C=O).
216
Experiment 64
3-(2-iodobenzyl)-3-hydroxy-2-methylisoindolin-1-one (82a) (SG-71)
N
O
CH3
HO
C16H14INO2Mol. Wt.: 379.19 g/mol
I
General procedure (A) was followed, with slight modification of halving the amounts
used and thus using a 50 ml Schlenk flask, using NMP (0.1 g, 0.76 mmol), 2-
iodophenylacetic acid (0.6 g, 2.26 mmol) and K2CO3 (0.2 g, 1.12 mmol). After 4 hr
the TLC showed a product was formed. The solution was colourless, however a
precipitate was visible at this point, which was filtered and found to have a yield of
0.1 g and was shown by 1H-NMR to be the desired product. Following work-up of
the filtrate, the crude yield was found to be 0.4 g. The precipitate was combined with
the crude product and column chromatography performed. The product was collected
in fractions 5-15 and seen to be a colourless powder which was confirmed to be the
pure product by 1H-NMR. The yield of the pure product was 0.1 g (0.39 mmol,
51%).
1H–NMR: (400 MHz, C2D6CO): δ (ppm) = 3.00 (s; 3H; NCH3), 3.26 (d; 2J =
14.0Hz; 1H; CH2), 3.68 (d; 2J = 14.4Hz; 1H; CH2), 6.42 (br.s; 1H; OH), 6.95 (ddd; 3J
= 7.6Hz; 4J = 1.6Hz; 1H; CHarom), 7.04 (m; 1H; CHarom), 7.29 (ddd; 3J = 7.6Hz; 4J =
1.2Hz; 1H; CHarom), 7.35 (dd; 3J = 7.6Hz; 4J = 1.6Hz; 1H; CHarom), 7.41-7.47 (br.m;
2H; CHarom), 7.58-7.62 (m; 1H; CHarom), 7.76 (dd; 3J = 8.0Hz; 4J = 1.2Hz; 1H;
CHarom). 13C–NMR: (100 MHz, C2D6CO): δ (ppm) = 24.0 (1C; NCH3), 47.7 (1C; CH2), 90.2
(1C; COH), 104.0 (1C; CI), 122.8 (1C; CHarom), 123.9 (1C; CHarom), 128.5 (1C;
CHarom), 129.3 (1C; CHarom), 129.6 (1C; CHarom), 131.4 (1C; CHarom), 131.8 (1C;
CHarom), 132.5 (1C; Cq), 139.6 (1C; Cq), 139.9 (1C; CHarom), 147.7 (1C; Cq), 166.5
(1C; C=O).
217
CAS No.: 1197385-30-0
Experiment 65
(Z)-3-(2-iodobenzylidene)-2-methylisoindolin-1-one (82b) (SG-76)
C16H12INOMol. Wt.: 361.18 g/mol
N
O
CH3
I
Following general procedure (C), 82a (0.1 g; 0.38 mmol) was stirred in of DCM (12
ml) and conc. HCl (4 ml) overnight. The product appeared as a yellow oily
crystalline solid and had a yield of 0.1 g; (0.34 mmol; 90%). The 1H-NMR confirmed
the desired product was formed. There was not enough product available to obtain a 13C NMR.
1H–NMR: (400 MHz, C2D6CO): δ (ppm) = 3.44 (s; 3H; NCH3), 6.50 (s; 1H; CHolef),
7.02 (d; 3J = 7.6Hz; 1H; CHarom), 7.26 (m; 1H; CHarom), 7.43 (ddd; 3J = 7.6Hz; 4J =
1.2Hz; 1H; CHarom), 7.53-7.58 (br.m; 2H; CHarom), 7.64 (dd; 3J = 7.6Hz; 4J = 1.2Hz;
1H; CHarom), 7.81 (d; 3J = 7.6Hz; 1H; CHarom), 8.10 (dd; 3J = 7.6Hz; 4J = 1.2Hz; 1H;
CHarom).
Literature reference No.: [153]
CAS No.: 202122-80-3
218
Experiment 66
5-methyl-5H-dibenz[cd,f]indol-4-one (82c) (SG-78)
N CH3
OC16H11NO
Mol. Wt.: 233.26 g/mol
82b (0.1 g; 0.34 mmol) was dissolved in 50 ml of benzene and placed in a 50 ml
Schlenk flask. This was placed in the photoreactor and the solution degassed with a
stream of N2 for a few minutes. The tube was then removed, and the reaction vessel
sealed and irradiated for 25 hr. The TLC showed a fluorescent spot so it was
assumed the product was formed. The solution was a dark pink in colour at this
point. The benzene was evaporated by rotary evaporation, water and DCM added and
the organic layer extracted, washed and dried as usual. The crude product had a yield
of 0.1 g and the 1H-NMR showed the product had been formed but was impure.
Column chromatography was performed using solvent system ethylacetate:hexane
(1:1). The product was seen to be collected in the second fraction with a yield of 0.02
g (0.08 mmol; 24%), and was a yellow, oily solid. The 1H-NMR obtained confirmed
this was the product, however it was still not entirely pure. There was not enough
product available to obtain a 13C NMR.
1H–NMR: (400 MHz, C2D6CO): δ (ppm) = 3.47 (s; 3H; NCH3), 7.39 (s; 1H;
CHarom), 7.62 (m; 2H; CHarom), 7.92 (t; 3J = 7.2Hz; 1H; CHarom), 7.99 (d; 3J = 7.6Hz;
1H; CHarom), 8.06 (d; 3J = 7.2Hz; 1H; CHarom), 8.70 (d; 3J = 8.0Hz; 1H; CHarom), 8.82
(d; 3J = 8.0Hz; 1H; CHarom).
Literature reference No.: [153]
CAS No.: 202122-84-7
219
Experiment 67
3-(2-iodo-4,5-dimethoxybenzyl)-3-hydroxy-2-methylisoindolin-1-one (83) (SG-
197)
C18H18INO4Mol. Wt.: 439.24 g/mol
N
O
CH3
HO
I
OCH3
OCH3
General procedure (A) was followed, with slight variation, using NMP (0.24 g, 1.50
mmol), 81a (1.23 g, 3.82 mmol) and K2CO3 (0.31 g, 2.26 mmol). There was not
enough acid available to add the usual 4.50 mmol although it was still used in excess.
After 8 hr the TLC showed the product was formed and the crude material found to
be 0.41 g. From the NMR it was evident that the product had been formed, however
NMP still remained and impurities were also present. The crude product was
purified, in the round bottom flask, by dissolving in a small amount of acetone and
adding hexane. This was then sonicated and the product seen to precipitate. This was
filtered and found to be a brown powder with a yield of 0.05 g (0.12 mmol; 8%). The
resulting 1H-NMR showed this to be the pure product.
1H–NMR: (400 MHz, C2D6CO): δ (ppm) = 3.05 (s; 3H; NCH3), 3.32 (d; 2J =
14.4Hz; 1H; CH2), 3.60 (s; 3H; OCH3), 3.65 (d; 2J = 14.4Hz; 1H; CH2), 3.75 (s; 3H;
OCH3), 5.44 (br.s; 1H; OH), 6.70 (s; 1H; CHarom), 7.16 (s; 1H; CHarom), 7.31 (dd; 3J
= 7.6Hz; 1H; CHarom), 7.43-7.52 (br.m; 2H; CHarom), 7.57 (dd; 3J = 6.8Hz; 1H;
CHarom).
220
Experiment 68
3-(2-iodo-4,5-dimethoxybenzyl)-3-hydroxy-2-methylisoindolin-1-one (83) (SG-
241)
C18H18INO4Mol. Wt.: 439.24 g/mol
N
O
CH3
HO
I
OCH3
OCH3
General procedure (A) was followed using NMP (0.24 g, 1.51 mmol), 81a (1.45 g,
4.50 mmol) and K2CO3 (0.31 g, 2.25 mmol). After 16.5 hr the reaction was worked
up and the crude material found to have a yield of 0.85 g. The 1H-NMR showed the
product was formed but NMP still dominated. Purification was carried out by
washing with a small amount of acetone and the product isolated in a yield of 0.06 g
(0.14 mmol; 9%).
For 1H-NMR data see experiment 67.
Experiment 69
3-(2-iodo-4,5-dimethoxybenzyl)-3-hydroxy-2-methylisoindolin-1-one (83) (SG-
244)
C18H18INO4Mol. Wt.: 439.24 g/mol
N
O
CH3
HO
I
OCH3
OCH3
General procedure (A) was followed, with the slight variation of halving the amounts
used and therefore performing the reaction in a 50 ml Schlenk flask, using NMP
(0.12 g, 0.75 mmol), 81a (0.73 g, 2.25 mmol) and K2CO3 (0.16 g, 1.13 mmol). After
221
31 hr the reaction was stopped and the precipitate, which was visible throughout the
reaction, was filtered after the acetone had been evaporated. The 1H-NMR showed
this to be mainly 81a however a small amount of NMP was also present. The filtrate
was then worked up as usual and the crude material found to have a yield of 0.30 g.
The 1H-NMR showed NMP to be the major component however purification was
carried out by washing with a small amount of acetone and the product isolated in a
yield of 0.03 g (0.08 mmol; 11%).
For 1H-NMR data see experiment 67.
Experiment 70
3-(2-iodo-3,4,5-trimethoxybenzyl)-3-hydroxy-2-methylisoindolin-1-one (84) (SG-
201)
N
O
CH3
HO
I
OCH3
OCH3
C19H20INO5Mol. Wt.: 469.27 g/mol
OCH3
General procedure (A) was followed using NMP (0.24 g, 1.50 mmol), 81b (1.58 g,
4.50 mmol) and K2CO3 (0.31 g, 2.25 mmol). After 13 hr the TLC showed the
product was formed and the crude material found to be 0.85 g. From the 1H-NMR it
was evident that the product had been formed, however NMP still remained and
impurities were also present. The crude product was purified, in the round bottom
flask, by dissolving in a small amount of acetone and adding hexane. This was then
sonicated and the product seen to precipitate. This was filtered and found to be a
yellow powder with a yield of 0.24 g (0.50 mmol; 33%). The resulting 1H-NMR
showed this to be the pure product.
1H–NMR: (400 MHz, C2D6CO): δ (ppm) = 3.04 (s; 3H; NCH3), 3.32 (d; 2J =
14.4Hz; 1H; CH2), 3.68 (s; 3H; OCH3), 3.71 (s; 3H; OCH3), 3.75 (d; 2J = 14.0Hz;
1H; CH2), 3.76 (s; 3H; OCH3), 5.43 (br.s; 1H; OH), 6.70 (s; 1H; CHarom), 7.21 (dd; 3J
222
= 6.0Hz; 1H; CHarom), 7.42-7.49 (br.m; 2H; CHarom), 7.57 (dd; 3J = 6.0Hz; 1H;
CHarom). 13C–NMR: (100 MHz, C2D6CO): δ (ppm) = 24.1 (1C; NCH3), 47.4 (1C; CH2), 56.1
(1C; OCH3), 60.7 (1C; OCH3), 60.9 (1C; OCH3), 90.6 (1C; C-OH), 92.0 (1C; CI),
110.6 (1C; CHarom), 122.8 (1C; CHarom), 124.1 (1C; CHarom), 129.7 (1C; CHarom),
131.9 (1C; CHarom), 132.9 (1C; Cq), 135.1 (1C; Cq), 141.8 (1C; Cq), 147.8 (1C; Cq),
153.4 (1C; Cq), 153.8 (1C; Cq), 166.6 (1C; C=O).
Experiment 71
3-(2-iodo-3,4,5-trimethoxybenzyl)-3-hydroxy-2-methylisoindolin-1-one (84) (SG-
242)
N
O
CH3
HO
I
OCH3
OCH3
C19H20INO5Mol. Wt.: 469.27 g/mol
OCH3
General procedure (A) was followed using NMP (0.24 g, 1.50 mmol), 81b (1.58 g,
4.49 mmol) and K2CO3 (0.31 g, 2.25 mmol). After 16.5 hr the reaction was worked
up and the crude material found to have a yield of 0.85 g. Purification was carried
out by washing with a small amount of acetone and the product isolated in a yield of
0.25 g (0.53 mmol; 35%).
For 1H-NMR data see experiment 201.
223
Experiment 72
3-(2-iodo-3,4,5-trimethoxybenzyl)-3-hydroxy-2-methylisoindolin-1-one (84) (SG-
245)
N
O
CH3
HO
I
OCH3
OCH3
C19H20INO5Mol. Wt.: 469.27 g/mol
OCH3
General procedure (A) was followed, with the slight variation of halving the amounts
used and therefore performing the reaction in a 50 ml Schlenk flask, using NMP
(0.12 g, 0.76 mmol), 81b (0.79 g, 2.25 mmol) and K2CO3 (0.16 g, 1.13 mmol). After
31 hr the reaction was worked up and the crude material found to have a yield of
0.60 g. Purification was carried out by washing with a small amount of acetone and
the product isolated in a yield of 0.26 g (0.53 mmol; 35%).
For 1H-NMR data see experiment 201.
Experiment 73
(E) and (Z)-3-(2-iodo-3,4,5-trimethoxybenzylidene)-2-methylisoindolin-1-one
(85) (SG-208)
N
O
CH3
I
H3CO
H3CO OCH3
C19H18INO4Mol. Wt.: 451.25 g/mol
Following general procedure (C) 84 (0.23 g; 0.50 mmol) was stirred in of DCM (12
ml) and conc. HCl (4 drops) and the mixture stirred overnight. The product appeared
224
as a yellow oily solid and had a yield of 0.21 g; (0.47 mmol; 94%). The 1H-NMR
confirmed the desired product was formed, however both isomers were present in a
ratio of 83:17.
Major Isomer: 1H–NMR: (400 MHz, C2D6CO): δ (ppm) = 3.39 (s; 3H; NCH3), 3.83 (s; 3H; OCH3),
3.89 (s; 3H; OCH3), 3.91 (s; 3H; OCH3), 6.41 (s; 1H; CHolef), 7.12 (s; 1H; CHarom),
7.19 (dd; 3J = 7.6Hz; 4J = 0.8Hz; 1H; CHarom), 7.44 (ddd; 3J = 7.6Hz; 4J = 1.2Hz; 1H;
CHarom), 7.51 (ddd; 3J = 7.6Hz; 4J = 1.2Hz; 1H; CHarom), 7.76 (dd; 3J = 7.6Hz; 4J =
0.8Hz; 1H; CHarom).
Minor Isomer: 1H–NMR: (400 MHz, C2D6CO): δ (ppm) = 3.39 (s; 3H; NCH3), 3.87 (s; 3H; OCH3),
3.88 (s; 3H; OCH3), 3.92 (s; 3H; OCH3), 6.68 (s; 1H; CHolef), 7.03 (s; 1H; CHarom),
7.24 (dd; 3J = 7.2Hz; 4J = 0.8Hz; 1H; CHarom), 7.59 (ddd; 3J = 7.6Hz; 4J = 1.2Hz; 1H;
CHarom), 7.71 (ddd; 3J = 7.6Hz; 4J = 1.2Hz; 1H; CHarom), 8.02 (dd; 3J = 7.6Hz; 4J =
0.8Hz; 1H; CHarom).
Experiment 74
Trimethoxy-substituted aristolactam (86) (SG-213)
N
O
CH3
OCH3
H3CO
H3CO
C19H17NO4Mol. Wt.: 323.34 g/mol
85 (0.02 g; 0.04 mmol) was placed in an NMR tube, dissolved in benzene-d6 (0.75
ml) degassed briefly with nitrogen and irradiated in the Rayonet photoreactor. An
NMR study was performed on this reaction by obtaining a 1H-NMR periodically. 1H-
NMR’s were obtained for this reaction at 0 hr, 0.25 hr, 0.50 hr, 0.75 hr, 1 hr, 2 hr, 3
hr, 4 hr, 5 hr, 6 hr, 7 hr, 8 hr, 9 hr, 10 hr, 11 hr, 12 hr, 13 hr, 14 hr, 15 hr, 16 hr, 17 hr,
18 hr, 19 hr and 36 hr. This enabled us to see the E-Z isomerisation occurring
225
initially, and then the eventual formation of the aristolactam. The product was seen to
be present in a minor quantity after 4 hr and formation increased gradually until it
was clearly visible at 36 hr even though both isomers of the starting material were
still present.
For 1H-NMR data see experiment 218.
Experiment 75
Trimethoxy-substituted aristolactam (86) (SG-218)
N
O
CH3
OCH3
H3CO
H3CO
C19H17NO4Mol. Wt.: 323.34 g/mol
85 (0.01 g; 0.03 mmol) and DDQ (0.04 g; 0.16 mmol) were placed in an NMR tube,
dissolved in benzene-d6 (0.75 ml) degassed briefly with nitrogen and irradiated in
the Rayonet photoreactor. An NMR study was performed on this reaction by
obtaining a 1H-NMR periodically. 1H-NMR’s were obtained for this reaction at 1 hr,
2 hr, 4 hr, 6 hr, 8 hr, 10 hr, 12 hr, 14 hr, 16 hr, 18 hr, 20 hr, 22 hr and 25 hr. This
enabled us to see the E-Z isomerisation occurring initially, and then the eventual
formation of the aristolactam. The product was seen to be present in a minor quantity
after 2 hr and formation increased gradually until it was clearly visible at 36 hr. A
significant decrease in the presence of the isomers of the starting material resulted in
quite a clear 1H-NMR spetrum.
1H–NMR: (400 MHz, C6D6): δ (ppm) = 3.11 (s; 3H; NCH3), 3.61 (s; 3H; OCH3),
3.82 (s; 3H; OCH3), 3.93 (s; 3H; OCH3), 6.28 (s; 1H; CHarom), 6.65 (s; 1H; CHarom),
7.42 (ddd; 3J = 7.2Hz; 4J = 0.8Hz; 1H; CHarom), 7.95 (d; 3J = 7.2Hz; 1H; CHarom),
9.00 (d; 3J = 8.0Hz; 1H; CHarom).
226
Experiment 76
3-(3,4-dimethoxybenzyl)-3-hydroxy-5,6-dimethoxy-2-methylisoindolin-1-one
(88) (SG-220)
N
O
CH3
HO OCH3
OCH3
H3CO
H3CO
C20H23NO6Mol. Wt.: 373.4 g/mol
General procedure (A) was followed using 79d (0.33 g, 1.50 mmol), 3,4,-
dimethoxyphenylacetic acid (0.88 g, 4.50 mmol) and K2CO3 (0.31 g, 2.25 mmol).
After 8 hr the reaction was stopped and a precipitate which was visible throughout
the reaction filtered and found to be a colourless powder with a yield of 0.24 g. The 1H-NMR showed this to be a mixture of 79d and the acid starting material. The
filtrate was worked up as usual and the crude material found to have a yield of 0.36
g. From the 1H-NMR it was evident that the product had been formed, however was
not pure. The crude product was purified by dissolving it in a small amount of
acetone, adding hexane and sonicating. The precipitate formed was filtered and
found to be a colourless powder with a yield of 0.12 g (0.32 mmol; 21%). The
resulting 1H-NMR showed this to be the desired product.
1H–NMR: (400 MHz, C2D6CO): δ (ppm) = 3.01 (s; 3H; NCH3), 3.18 (d; 3J =
14.0Hz; 1H; CH2), 3.41 (d; 3J = 14.0Hz; 1H; CH2), 3.54 (s; 3H; OCH3), 3.68 (s; 3H;
OCH3), 3.82 (s; 3H; OCH3), 3.89 (s; 3H; OCH3), 5.15 (br.s; 1H; OH), 6.45 (d; 4J =
2.0Hz; 1H; CHarom), 6.52 (dd; 3J = 8.4Hz; 4J = 2.0Hz; 1H; CHarom), 6.67 (d; 3J =
8.0Hz; 1H; CHarom), 6.94 (s; 1H; CHarom), 7.12 (s; 1H; CHarom).
227
Experiment 77
3-(3,4,5-trimethoxybenzyl)-3-hydroxy-5,6-dimethoxy-2-methylisoindolin-1-one
(89) (SG-219)
N
O
CH3
HO OCH3
OCH3
OCH3
C21H25NO7Mol. Wt.: 403.43 g/mol
H3CO
H3CO
General procedure (A) was followed using 79d (0.33 g, 1.50 mmol), 3,4,5-
trimethoxyphenylacetic acid (1.02 g, 4.50 mmol) and K2CO3 (0.31 g, 2.26 mmol).
After 8 hr the reaction was stopped and the precipitate formed during the reaction
filtered and found to be a colourless powder with a yield of 0.54 g (1.33; 89%). The 1H-NMR showed this to be the desired product. The filtrate was worked up as usual
and the crude material found to be 0.17 g. From the 1H-NMR it was evident that the
product had been formed, however was not pure. The crude product was purified by
dissolving the impurities in a small amount of acetone and the removing the solvent.
This was repeated several times and the product found to be a colourless powder
with a yield of 0.05 g (0.12 mmol; 8%). The resulting 1H-NMR showed this to also
be the pure product. [Overall yield = 97%].
1H–NMR: (400 MHz, C2D6CO): δ (ppm) = 3.00 (s; 3H; NCH3), 3.14 (d; 3J =
13.6Hz; 1H; CH2), 3.38 (d; 3J = 14.0Hz; 1H; CH2), 3.57 (s; 3H; OCH3), 3.58 (s; 6H;
2 × OCH3), 3.81 (s; 3H; OCH3), 3.89 (s; 3H; OCH3), 6.19 (br.s; 1H; OH), 6.20 (s;
2H; CHarom), 6.99 (s; 1H; CHarom), 7.16 (s; 1H; CHarom).
Literature reference No.: [65]
CAS No.: 813460-05-8
228
Experiment 78
(E) and (Z)-3-(3,4-dimethoxybenzylidene)-5,6-dimethoxy-2-methylisoindolin-1-
one (90) (SG-225)
N
O
CH3
H3CO OCH3
H3CO
H3CO
C20H21NO5Mol. Wt.: 355.38 g/mol
Following general procedure (C) 88 (0.12 g; 0.32 mmol) was stirred in DCM (15 ml)
and conc. HCl (2 ml) overnight. The crude product had a yield of 0.11 g, (0.31
mmol; 97%) and the 1H-NMR confirmed the desired product was present, however
both isomers were formed in a ratio of 74:26.
Major Isomer: 1H–NMR: (400 MHz, C2D6CO): δ (ppm) = 2.84 (s; 3H; NCH3), 3.28 (s; 3H; OCH3),
3.57 (s; 3H; OCH3), 3.84 (s; 3H; OCH3), 3.90 (s; 3H; OCH3), 6.50 (s; 1H; CHolef),
7.00 (s; 1H; CHarom), 7.07 (dd; 3J = 2.0Hz; 1H; CHarom), 7.18 (dd; 3J = 1.2Hz; 1H;
CHarom), 7.51 (s; 1H; CHarom).
229
Experiment 79
(E) and (Z)-3-(3,4,5-trimethoxybenzylidene)-5,6-dimethoxy-2-methylisoindolin-
1-one (91) (SG-222)
N
O
CH3
H3CO OCH3
H3CO
H3CO
H3CO
C21H23NO6Mol. Wt.: 385.41 g/mol
Following general procedure (C) 89 (0.53 g; 1.30 mmol) was stirred in DCM (15 ml)
and conc. HCl (2 ml) overnight. The crude product had a yield of 0.49 g, (1.28
mmol; 98%) and the 1H-NMR confirmed the desired product was present; however
both isomers were formed in a ratio of 78:22.
Major Isomer: 1H–NMR: (400 MHz, C2D6CO): δ (ppm) = 3.28 (s; 3H; NCH3), 3.58 (s; 3H; OCH3),
3.77 (s; 3H; OCH3), 3.85 (s; 6H; 2 × OCH3), 3.90 (s; 3H; OCH3), 6.51 (s; 1H;
CHolef), 6.80 (dd; 4J = 0.4Hz; 2H; CHarom), 6.90 (s; 1H; CHarom), 7.19 (s; 1H; CHarom).
Minor Isomer: 1H–NMR: (400 MHz, C2D6CO): δ (ppm) = 3.03 (s; 3H; NCH3), 3.68 (s; 3H; OCH3),
3.87 (s; 6H; 2 × OCH3), 3.93 (s; 3H; OCH3), 3.96 (s; 3H; OCH3), 6.51 (s; 1H;
CHolef), 6.69 (dd; 4J = 0.4Hz; 2H; CHarom), 7.19 (s; 1H; CHarom), 7.51 (s; 1H; CHarom).
230
Experiment 80
SG-230
N
O
CH3
OCH3
H3CO
H3CO
H3CO
C20H19NO5Mol. Wt.: 353.37 g/mol
90 (0.01 g; 0.02 mmol) and DDQ (0.01 g; 0.02 mmol) were placed in an NMR tube,
dissolved in benzene-d6 (0.75 ml) and irradiated in the Rayonet photoreactor. 1H-
NMR’s were obtained after 23 hr and 35 hr. There was no aristolactam formed
during this reaction.
Experiment 81
SG-231
N
O
CH3
OCH3
H3CO
H3CO
H3CO
C20H19NO5Mol. Wt.: 353.37 g/mol
90 (0.01 g; 0.02 mmol) was placed in an NMR tube, dissolved in benzene-d6 (0.75
ml) and irradiated in the Rayonet photoreactor. 1H-NMR’s were obtained after 23 hr
and 35 hr. There was no evidence of the aristolactam being formed during this
reaction.
231
Experiment 82
SG-230a
N
O
CH3
OCH3
H3CO
H3CO
H3CO
C20H19NO5Mol. Wt.: 353.37 g/mol
90 (0.20 g; 0.55 mmol) and DDQ (0.12 g; 0.55 mmol) were stirred in benzene (30
ml) at R.T for 48 hr. The solvent was then evaporated by rotary evaporation and the
product found to have a yield of 0.20 g. The 1H-NMR showed this to be 90 and it
was evident that no aristolactam was formed during this reaction.
Experiment 83
SG-228
N
O
CH3
OCH3
H3CO
H3CO
H3CO
H3CO
C21H21NO6Mol. Wt.: 383.39 g/mol
91 (0.01 g; 0.02 mmol) and DDQ (0.01 g; 0.02 mmol) were placed in an NMR tube,
dissolved in benzene-d6 (0.75 ml) and irradiated in the Rayonet photoreactor. 1H-
NMR’s were obtained after 25 hr and 35 hr. There was no aristolactam formed
during this reaction.
232
Experiment 84
SG-229
N
O
CH3
OCH3
H3CO
H3CO
H3CO
H3CO
C21H21NO6Mol. Wt.: 383.39 g/mol
91 (0.01 g; 0.02 mmol) was placed in an NMR tube, dissolved in benzene-d6 (0.75
ml) and irradiated in the Rayonet photoreactor. 1H-NMR’s were obtained after 25 hr
and 35 hr. There was no aristolactam formed during this reaction.
Experiment 85
SG-234
N
O
CH3
OCH3
H3CO
H3CO
H3CO
H3CO
C21H21NO6Mol. Wt.: 383.39 g/mol
91 (0.21 g; 0.55 mmol) and DDQ (0.12 g; 0.55 mmol) were stirred in benzene (30
ml) at R.T for 48 hr. The solvent was then evaporated by rotary evaporation and the
product found to have a yield of 0.21 g. The 1H-NMR showed this to be 91 and it
was evident that no aristolactam was formed during this reaction.
233
Experiment 86
SG-233
N
O
CH3
HO OCH3
OCH3
H3CO
H3CO
C20H22INO6Mol. Wt.: 499.3 g/mol
I
General procedure (A) was followed, with slight variation, using 79d (0.17 g, 0.77
mmol), 81a (0.73 g, 2.25 mmol) and K2CO3 (0.16 g, 1.14 mmol). As the quantities
were halved for this reaction, the irradiation was performed in a 50 ml Schlenk flask.
After 32 hr the reaction was stopped and the precipitate which was visible throughout
the reaction was filtered, after evaporating the acetone, and found to have a yield of
0.09 g. The 1H-NMR showed this to be 79d. The filtrate was worked up as usual and
the crude material found to have a yield of 0.22 g. The 1H-NMR showed that the
product had not been formed and unreacted 79d was also visible.
Experiment 87
SG-263
N
O
CH3
HO OCH3
OCH3
H3CO
H3CO
I
C21H24INO7Mol. Wt.: 529.32 g/mol
OCH3
General procedure (A) was followed, with slight variation, using 79d (0.33 g, 1.50
mmol), 81b (1.58 g, 4.50 mmol) and K2CO3 (0.31 g, 2.27 mmol). This reaction was
not cooled as usual, to encourage the starting materials to dissolve. After 53 hr the
reaction was stopped and the precipitate which was visible throughout the reaction
was filtered, after evaporating the acetone, and found to have a yield of 0.35 g. The
234
1H-NMR showed this to be 79d. The filtrate was worked up as usual and the crude
material found to have a yield of 0.69 g. The 1H-NMR showed that the product had
not been formed and unreacted 79d was also visible.
Experiment88
Stability test of 79d (SG-282)
N
O
O
CH3
H3CO
H3CO
C11H11NO4Mol. Wt.: 221.21 g/mol
A stability test was performed on SG-256 (0.10 g; 0.46 mmol) by dissolving in DMF
(50 ml) and irradiating it at 300nm overnight. The DMF was distilled, the product
dried under vacuum and the yield found to be 0.08 g, (0.36 mmol; 78%). The 1H-
NMR obtained showed no change in the starting material.
Experiment 89
SG-263a
N
O
CH3
HO OCH3
OCH3
H3CO
H3CO
I
C21H24INO7Mol. Wt.: 529.32 g/mol
OCH3
General procedure (A) was followed, with the variation of reducing the amounts and
performing the reaction in a 20 ml pyrex tube, using 79d (0.06 g; 0.30 mmol), 81b
(0.32 g; 0.90 mmol) and K2CO3 (0.06 g; 0.45 mmol). A solvent system of
acetone:water (2:1) was made up and used to dissolve the reagents. There wasn’t
much improvement in dissolving the reagents and following irradiation for 24 hr, the 1H-NMR showed the presence of 79d and no evidence of product formation.
235
Experiment 90
SG-263b
N
O
CH3
HO OCH3
OCH3
H3CO
H3CO
I
C21H24INO7Mol. Wt.: 529.32 g/mol
OCH3
General procedure (A) was followed, with the variation of reducing the amounts and
performing the reaction in a 20 ml pyrex tube, using 79d (0.06 g; 0.29 mmol), 81b
(0.32 g; 0.90 mmol) and K2CO3 (0.06 g; 0.45 mmol). A solvent system of
acetone:water (4:1) was made up and used to dissolve the reagents. This resulted in a
slight improvement in dissolving the reagents however, the starting material 79d was
seen to precipitate during the reaction. The irradiation period was 28 hr. Following
work-up, the 1H-NMR showed no evidence of product formation.
Experiment 91
SG-263c
N
O
CH3
HO OCH3
OCH3
H3CO
H3CO
I
C21H24INO7Mol. Wt.: 529.32 g/mol
OCH3
General procedure (A) was followed, with the variation of reducing the amounts and
performing the reaction in a 20 ml pyrex tube, using 79d (0.06 g; 0.30 mmol), 81b
(0.32 g; 0.90 mmol) and K2CO3 (0.06 g; 0.45 mmol). A solvent system of
acetone:water (10:1) was used to dissolve the reagents which showed a noticeable
improvement in dissolving the reagents. The reaction was irradiated for 24 hr, and
236
following work-up the 1H-NMR showed the presence of 79d and no evidence of
product formation.
Experiment 92
SG-264
N
O
CH3
HO OCH3
OCH3
H3CO
H3CO
I
C21H24INO7Mol. Wt.: 529.32 g/mol
OCH3
General procedure (A) was followed, with the slight variation of using acetone:DCM
1:1 as the solvent and halving all amounts, using 79d (0.17 g, 0.75 mmol), 81b (0.79
g, 2.25 mmol) and K2CO3 (0.16 g, 1.12 mmol). This reaction was not cooled as
usual, to encourage the starting materials to dissolve. (After 9.5 hr ~10 ml of H2O
was added to encourage solvation of the reagents, while the N2 was bubbled through
quite vigorously to homogenise the solution.) After 31 hr the reaction was stopped,
the DCM evaporated, H2O added and then worked up as usual. The crude material
was found to have a yield of 0.54 g. The 1H-NMR showed that the product had not
been formed, and a substantial amount of unreacted 79d was also visible.
Experiment 93
SG-283
N
O
CH3
HO OCH3
OCH3
H3CO
H3CO
I
C21H24INO7Mol. Wt.: 529.32 g/mol
OCH3
237
General procedure (A) was followed, with variations, using 79d (0.17 g; 0.75 mmol),
81b (0.79 g; 2.25 mmol) and K2CO3 (0.15 g; 1.12 mmol). A solvent system of
(acetone:water):DMF (4:1) was made up and used to dissolve the reagents. DMF
encouraged the starting materials to go into solution initially; however 79d did
precipitate during irradiation. The reaction was stopped after 25 hr and following
work-up, the 1H-NMR showed no evidence of product formation.
Experiment 94
SG-283a
N
O
CH3
HO OCH3
OCH3
H3CO
H3CO
I
C21H24INO7Mol. Wt.: 529.32 g/mol
OCH3
General procedure (A) was followed, with variations, using 79d (0.16 g; 0.76 mmol),
81b (0.79 g; 2.25 mmol) and K2CO3 (0.15 g; 1.12 mmol). A solvent system of
(acetone:water):DMF (1:1) was made up and used to dissolve the reagents. This
solvent system proved effective at dissolving the reagents; however following
irradiation for 24 hr, the crude 1H-NMR showed no evidence of the desired product.
Following purification by washing with a small amount of acetone, 79d was
recovered in a yield of 0.10 g.
Experiment 95
SG-329
N
O
CH3
HO OCH3
OCH3
H3CO
H3CO
I
C21H24INO7Mol. Wt.: 529.32 g/mol
OCH3
238
General procedure (A) was followed, with the variation of substituting H2O for an
ethanolic emulsion, quartering the amounts used and performing the reaction in a 50
ml Schlenk flask, using 79d (0.08 g, 0.38 mmol), 81b (0.40 g, 1.12 mmol) and
K2CO3 (0.08 g, 0.56 mmol). The reaction was performed at a low concentration to
encourage the starting materials to dissolve. The reaction was irradiated for 25 hr and
the precipitate, which was visible throughout the reaction, was filtered and found to
have a yield of 0.05 g. The 1H-NMR showed this to be 79d and there was no
evidence of the desired product.
Experiment 96
3-(2-iodobenzyl)-3-hydroxyisoindolin-1-one (92) (SG-341)
C15H12INO2Mol. Wt.: 365.17 g/mol
NH
O
HO
I
The general procedure (A1) was followed, with slight variation, using phthalimide
(0.22 g; 1.50 mmol), 2-iodophenylacetic acid (1.18 g, 4.50 mmol) and K2CO3 (0.31
g, 2.26 mmol). After 6 hr irradiation, the reaction was stopped and following work-
up, the product was found to be a yellow oily solid with a yield of 0.58 g.
Purification was carried out by washing with a small amount of acetone and the yield
found to be 0.43 g (1.17 mmol; 78%). The 1H-NMR obtained showed this to be the
desired product.
1H–NMR: (400 MHz, C2D6CO): δ (ppm) = 3.55 (d; 2J = 14.0Hz; 1H; CH2), 3.60 (d; 2J = 14.0Hz; 1H; CH2), 5.50 (br.s; 1H; OH), 6.94 (ddd; 3J = 7.6Hz; 4J = 1.6Hz; 1H;
CHarom), 7.26 (ddd; 3J = 7.6Hz; 4J = 1.2Hz; 1H; CHarom), 7.36 (ddd; 3J = 7.2Hz; 4J =
0.8Hz; 1H; CHarom), 7.46 (ddd; 3J = 7.2Hz; 4J = 0.8Hz; 2H; CHarom), 7.54 (m; 2H;
CHarom), 7.79 (dd; 3J = 8.0Hz; 4J = 1.2Hz;1H; CHarom), 7.87 (dd; 3J = 8.0Hz; 4J =
1.2Hz; 1H; CHarom), 7.93 (br.s; 1H; NH).
239
CAS No.: 1246376-50-0
Experiment 97
SG-344
NH
O
HO
I
C17H16INO4Mol. Wt.: 425.22 g/mol
OCH3
OCH3
General procedure (A1) was followed, with the slight variation of reducing amounts
and performing the reaction in a 20 ml pyrex flask, using phthalimide (0.04 g, 0.30
mmol) instead of the usual NMP, 81a (0.29 g, 0.90 mmol) and K2CO3 (0.06 g, 0.45
mmol). After 23 hr the reaction was stopped and following work-up, the product was
found to be a yellow oily solid with a yield of 0.16 g. The 1H-NMR showed this to be
a mix of starting materials. The crude product was purified by washing with a small
amount of acetone and 81a was recovered. The desired product was not obtained.
Experiment 98
SG-343
NH
O
HO
I
OCH3
OCH3OCH3
C18H18INO5Mol. Wt.: 455.24 g/mol
General procedure (A1) was followed, with the slight variation of reducing amounts
and performing the reaction in a 20 ml pyrex flask, using phthalimide (0.05 g, 0.31
mmol), 81a (0.32 g, 0.90 mmol) and K2CO3 (0.06 g, 0.45 mmol). After 23 hr the
240
reaction was stopped and following work-up, the product was found to be a brown
oily solid with a yield of 0.14 g. The 1H-NMR showed this to be a mix of starting
materials. There was no evidence of the desired product.
Experiment 99
SG-346
NH
O
HO
I
H3CO
H3CO
C17H16INO4Mol. Wt.: 425.22 g/mol
General procedure (A1) was followed, with the slight variation of reducing the
amounts (the reaction was still performed in a 100 ml Schlenk flask), using 79e (0.03
g, 0.15 mmol), 2-iodophenylacetic acid (0.12 g, 0.45 mmol) and K2CO3 (0.03 g, 0.23
mmol). The solvent used was (acetone:pH 7 buffer):formamide 7:3. After 21 hr of
irradiation the reaction was stopped and following work-up, the 1H-NMR showed the
desired product was not obtained.
Experiment 100
SG-345
NH
O
HO
I
H3CO
H3CO
OCH3
OCH3
C19H20INO6Mol. Wt.: 485.27 g/mol
General procedure (A1) was followed, with the slight variation of reducing the
amounts (the reaction was still performed in a 100 ml Schlenk flask), using 79e (0.03
g, 0.15 mmol), 81a (0.14 g, 0.45 mmol) and K2CO3 (0.03 g, 0.23 mmol). The solvent
241
used was (acetone:pH 7 buffer):DMF 7:3. After 21 hr of irradiation the reaction was
stopped and following work-up, the 1H-NMR showed the desired product was not
obtained.
Experiment 101
SG-342
NH
O
HO
I
OCH3
OCH3OCH3
H3CO
H3CO
C20H22INO7Mol. Wt.: 515.3 g/mol
General procedure (A1) was followed, with the slight variation of reducing the
amounts and performing the reaction in a 20 ml pyrex tube, using 79e (0.03 g, 0.15
mmol), 81b (0.16 g, 0.45 mmol) and K2CO3 (0.03 g, 0.23 mmol). The solvent used
was (acetone:pH 7 buffer):DMF 3:1. After 45.5 hr of irradiation the reaction was
stopped, the precipitate formed was isolated and found to be the starting material 79e
in a yield of 0.02 g. Following work-up, the 1H-NMR of the crude product showed
the desired product was not obtained.
Experiment 102
SG-270
C21H24INO7Mol. Wt.: 529.32 g/mol
N
O
CH3
HO
I
H3CO
H3CO
OCH3
OCH3
OCH3
The general procedure (E) was followed using silver trifluoroacetate (0.04 g; 0.20
mmol), 89 (0.09 g; 0.19 mmol) and iodine (0.05 g; 0.22 mmol), (DCM 15 ml). The
242
crude yield was found to be 0.06 g. The 1H-NMR showed a lot of impurities so
column chromatography was performed using solvent system ethyl acetate:hexane
1:1. The product was thought to be collected in fractions 2-3, however the 1H-NMR
showed this to be 79d. This reaction was not successful.
Experiment 103
SG-271
C21H22INO6Mol. Wt.: 511.31 g/mol
N
O
CH3
I
H3CO
H3CO OCH3
H3CO
H3CO
The general procedure (E) was followed using silver trifluoroacetate (0.04 g; 0.17
mmol), 91 (0.07 g; 0.17 mmol) and iodine (0.04 g; 0.17 mmol), (DCM 20 ml). The
crude yield was found to be 0.10 g. The 1H-NMR showed no evidence of the desired
product being formed.
Additional reactions:
3-(3,4,5-trimethoxybenzyl)-3-hydroxy-2-methylisoindolin-1-one
SG-4
N
O
CH3
HO OCH3
OCH3
OCH3
C19H21NO5Mol. Wt.: 343.37 g/mol
General procedure (A) was followed using NMP (0.2 g, 1.51 mmol), 3,4,5-
trimethoxyphenylacetic acid (1.0 g, 4.50 mmol) and K2CO3 (0.3 g, 2.25 mmol). After
243
1.5 hr the TLC showed a product was formed. The solution was clear and colourless.
The crude yield was found to be 1.1 g (3.29 mmol). Following column
chromatography it was assumed from the TLC that the desired product was collected
in fractions 2-5. The 1H-NMR obtained confirmed this and the overall weight of the
fractions was found to be 0.3 g, (0.75 mmol, 50%). The product was then further
recrystallised from acetone using hexane and formed a colourless, fine, powder-like
substance. The yield of the purified product was 0.1 g (0.30 mmol, 20%).
1H–NMR: (400 MHz, CDCl3) : δ (ppm) = 2.50 (br.s; 1H; OH), 3.06 (s; 3H; NCH3),
3.06 (d; 2J = 14.0Hz; 1H; CH2), 3.46 (d; 2J = 14.0Hz; 1H; CH2), 3.62 (s; 6H; o-
OCH3) 3.76 (s; 3H; p-OCH3) 6.07 (s; 2H; CHarom), 7.33 (d; 3J = 7.6Hz; 1H; CHarom),
7.44 (ddd; 3J = 7.6Hz; 4J = 1.2Hz; 1H; CHarom), 7.51 (ddd; 3J = 7.6Hz; 4J = 1.2Hz;
1H; CHarom), 7.67 (d; 3J = 7.6Hz; 1H; CHarom). 13C–NMR: (100 MHz, CDCl3): δ (ppm) = 23.9 (1C; NCH3), 42.7 (1C; CH2), 55.9
(2C; o-OCH3), 60.9 (1C; p-OCH3), 90.6 (1C; COH), 107.0 (2C; CHarom), 122.8 (1C;
CHarom), 123.2 (1C; CHarom), 129.7 (1C; CHarom), 129.9 (1C; Cqarom), 131.4 (1C;
Cqarom), 131.6 (1C; CHarom), 136.9 (1C; Cqarom), 146.2 (1C; p-C-OCH3), 152.6 (2C;
o-COCH3), 166.9 (1C; C=O).
CAS No.: 881376-83-6
SG-259
N
O
CH3
HO OCH3
OCH3
H3CO
H3CO
I
C20H22INO6Mol. Wt.: 499.3 g/mol
General procedure (A) was followed using 79d (0.31 g, 1.41 mmol), 81a (1.45 g,
4.50 mmol) and K2CO3 (0.31 g, 2.25 mmol). After 32 hr the reaction was stopped
and the precipitate, which was visible throughout the reaction, was filtered and found
to have a yield of 0.43 g. The 1H-NMR showed this to be 79d. The filtrate was
244
worked up as usual and the crude material found to have a yield of 0.38 g. The 1H-
NMR showed that the product had not been formed and unreacted 79d was also
visible.
7.4 Chapter 5: Synthesis of phthalocyanines from photochemically
derived fluorinated phthalonitriles
7.4.1 General Procedure (F):
TFPN (1.50 mmol) and methoxy-substituted benzene partner (3.00 mmol) were
dissolved in DCM (10 ml) and transferred to a 350 ml Schlenk flask which was then
filled up to the neck with DCM. This was placed in the Rayonet reactor, the cold
finger inserted and both neck openings sealed. The solution was irradiated at 300nm,
while being cooled, and the progress monitored by TLC. Upon completion of the
reaction, the DCM was removed by rotary evaporation and a 1H-NMR of the crude
product obtained. Column chromatography was carried out using solvent system
ethyl acetate:hexane (1:6). A 1H-NMR of the pure product was then obtained.
Experiment 104
Methoxy-substituted phthalonitrile derivative (95a) (SG-294)
F
FF
NC
NC
OCH3
C15H7F3N2OMol. Wt.: 288.22 g/mol
Following general procedure (F), TFPN (0.30 g; 1.51 mmol) and anisole (325 μl;
2.98 mmol) were irradiated in DCM for 70 hr. The crude yield was found to be 0.53
g and the 1H-NMR showed this to be a mixture of TFPN and the desired product.
Following purification, the product appeared as an off-white powder and was
collected in fractions 4-11 with a yield of 0.17 g, (0.59 mmol; 39%).
245
SG-295:
General procedure (F) was followed using TFPN (0.30 g; 1.50 mmol) and anisole
(325μl; 2.98 mmol). The solution was irradiated for 70 hr and the crude yield found
to be 0.59 g. The 1H-NMR showed this to be a mixture of TFPN and the desired
product. Following column chromatography, the pure product was collected in
fractions 5-25, and was seen to be an off-white powder with a yield of 0.19 g, (0.66
mmol; 44%).
[Average yield = 42%]
1H–NMR: (400 MHz, CDCl3): δ (ppm) = 3.89 (s; 3H; OCH3), 7.06 (dd; 3J = 8.8Hz; 4J = 2.0Hz; 2H; CHarom), 7.42 (dd; 3J = 8.8Hz; 4J = 1.6Hz; 2H; CHarom). 19F–NMR: (400 MHz, CDCl3/C6F6): δ (ppm) = -131.8 (q; J = 12Hz; 1F; CFarom), -
126.4 (q; J = 12Hz; 1F; CFarom), -109.2 (t; J = 12Hz; 1F; CFarom). 13C–NMR: (100 MHz, CDCl3): δ (ppm) = 55.6 (1C; OCH3), 114.8 (2C; CHarom),
131.6 (2C; CHarom), 161.7 (1C; Cq).
Literature reference No.: [142]
CAS No.: 75860-37-6
Experiment 105
Trimethoxy-substituted phthalonitrile derivative (95b) (SG-318/319)
F
FF
NC
NC
OCH3
OCH3
C16H9F3N2O2Mol. Wt.: 318.25 g/mol
General procedure (F) was followed for both reactions and the crude products
combined before performing column chromatography, using TFPN (0.30 g; 1.50
mmol/0.30 g; 1.50 mmol) and 1,3-dimethoxybenzene (393 μl; 3.00 mmol/393 μl;
3.00 mmol). The solution was irradiated for 96 hr and following column
246
chromatography, the pure product was collected in fractions 3-5, and was seen to be
an off-white powder with a yield of 0.47 g, (1.49 mmol; 50%).
1H–NMR: (400 MHz, CDCl3): δ (ppm) = 3.80 (s; 3H; OCH3), 3.88 (s; 3H; OCH3),
6.59 (d; 4J = 2.4Hz; 1H; CHarom), 6.63 (dd; 3J = 8.4Hz; 4J = 2.4Hz; 1H; CHarom), 7.14
(d; 3J = 8.4Hz; 1H; CHarom). 19F–NMR: (400 MHz, CDCl3/C6F6): δ (ppm) = -133.5 (q; J = 12Hz; 1F; CFarom), -
120.2 (q; J = 12Hz; 1F; CFarom), -104.2 (t; J = 12Hz; 1F; CFarom). 13C–NMR: (100 MHz, CDCl3): δ (ppm) = 55.7 (1C; OCH3), 55.9 (1C; OCH3), 99.1
(1C; CHarom), 105.5 (1C; CHarom), 131.9 (1C; CHarom), 158.2 (1C; Cq), 163.4 (1C;
Cq).
Literature reference No.: [142]
CAS No.: 75860-38-7
Experiment 106
Trimethoxy-substituted phthalonitrile derivative (95c) (SG-298/299)
F
FF
NC
NC
OCH3
OCH3
OCH3C17H11F3N2O3
Mol. Wt.: 348.28 g/mol
General procedure (F) was followed for both reactions and the crude products
combined before performing column chromatography, using TFPN (0.30 g; 1.51
mmol/0.30 g; 1.50 mmol) and 1,3,5-trimethoxybenzene (0.51 g; 3.00 mmol/0.51 g;
3.01 mmol). The solution was irradiated for 70 hr and the crude yield found to be
0.94 g/0.89 g. [Total yield = 1.84 g]. The 1H-NMR showed this to be a mixture of
TFPN and the desired product. Following column chromatography, the pure product
was collected in fractions 5-13, and was seen to be a yellow crystalline solid with a
yield of 0.49 g, (1.41 mmol; 47%).
247
1H–NMR: (400 MHz, CDCl3): δ (ppm) = 3.77 (s; 6H; 2 × OCH3), 3.88 (s; 3H;
OCH3), 6.21 (s; 2H; CHarom). 19F–NMR: (400 MHz, CDCl3/C6F6): δ (ppm) = -132.7 (q; J = 12Hz; 1F; CFarom), -
122.3 (q; J = 12Hz; 1F; CFarom), -106.9 (t; J = 12Hz; 1F; CFarom). 13C–NMR: (100 MHz, CDCl3): δ (ppm) = 55.7 (1C; OCH3), 56.0 (2C; 2 × OCH3),
90.8 (2C; CHarom), 158.8 (2C; Cq), 164.2 (1C; Cq).
Mass spec: [MS]: 348 m/z; expected 348 m/z
7.4.2 General procedure (G):
The desired methxoy-substituted phthalonitrile derivative were stirred at R.T in
TFA:H2SO4 (4:1) for 48 hr. The reaction was quenched by pouring onto ice-water.
This was extracted with ethyl acetate (×3), the organic layers combined, dried over
MgSO4 and the solvent evaporated. A crude 1H-NMR was obtained. Purification was
performed by recrystallisation from ethanol and a second 1H-NMR obtained.
Experiment 107
Sulfonated dimethoxy-substituted phthalonitrile derivative (96b) (SG-301)
F
FF
NC
NC
OCH3
OCH3
SO3HC16H9F3N2O5S
Mol. Wt.: 398.31 g/mol
Following general procedure (G) 95b (0.08 g; 0.26 mmol) was stirred at R.T in
TFA:H2SO4 (4:1) (8 ml) for 48 hr. The crude yield was found to be 0.12 g. The 1H-
NMR showed this to be a mixture of starting material and product. This was
recrystallised from ethanol, the precipitate formed was filtered, and the 1H-NMR
showed this not to be the product. The filtrate was then evaporated and the yield
found to be 0.09 g, (0.23 mmol; 88%). The 1H-NMR showed this to be the desired
product.
248
1H–NMR: (400 MHz, C2D6CO): δ (ppm) = 3.99 (s; 3H; OCH3), 4.07 (s; 3H; OCH3),
7.03 (s; 1H; CHarom), 7.84 (s; 1H; CHarom). 19F–NMR: (400 MHz, C2D6CO/C6F6): δ (ppm) = -133.0 (q; J = 12Hz; 1F; CFarom), -
122.5 (q; J = 12Hz; 1F; CFarom), -106.6 (t; J = 12Hz; 1F; CFarom). 13C–NMR: (100 MHz, C2D6CO): δ (ppm) = 56.9, 57.1, 97.7, 105.3, 123.3, 132.8,
154.4, 161.6, 162.2, 198.3.
Mass spec: [MS - H]: 397 m/z, expected: 398 m/z
Melting point: 112-115oC
Experiment 108
Sulfonated dimethoxy-substituted phthalonitrile derivative (96b) (SG-340)
F
FF
NC
NC
OCH3
OCH3
SO3HC16H9F3N2O5S
Mol. Wt.: 398.31 g/mol
General procedure (G) was followed, with the variation of using H2SO4 (4 ml) as the
sole solvent, using 95b (0.05 g; 0.16 mmol). The solution was stirred at R.T for 43
hr, then worked up. The 1H-NMR showed this to be the desired product which was
obtained in a yield of 0.02 g, (0.06 mmol; 38%). No purification was carried out.
For 1H-NMR data see experiment 107.
249
Experiment 109
Sulfonated dimethoxy-substituted phthalonitrile derivative (96b) (SG-347)
F
FF
NC
NC
OCH3
OCH3
SO3HC16H9F3N2O5S
Mol. Wt.: 398.31 g/mol
General procedure (G) was followed, with slight variation, using 95b (0.20 g; 0.63
mmol) and TFA:H2SO4 (1:1) (10 ml). The solution was stirred at R.T for 96 hr, then
worked up. The 1H-NMR showed this to be the desired product and was obtained in
a yield of 0.07 g, (0.18 mmol; 29%). No purification was carried out.
For 1H-NMR data see experiment 107.
Experiment 110
Sulfonated methoxy-substituted phthalonitrile derivative (96a) (SG-316)
F
FF
NC
NC
OCH3
SO3H
C15H7F3N2O4SMol. Wt.: 368.29 g/mol
Following general procedure (G) 95a (0.07 g; 0.26 mmol) was stirred in TFA:H2SO4
(4:1) (8 ml) overnight. The TLC showed the starting material spot had disappeared
so the reaction was quenched by pouring onto ice-water. A precipitate was formed
which was found to be a colourless powder with a yield of 0.03 g. The 1H-NMR was
very similar to the starting material, however a mass spectrum was also obtained
which implied that this was the anhydride of the starting material as there was a peak
at 308 m/z. However, the filtrate was also extracted with ethyl acetate (×3), the
organic layers combined and dried over MgSO4 and the solvent evaporated. The
crude yield was found to be 0.05 g and the 1H-NMR showed the presence of the
250
sulfonated product with the starting material 95a also present. Recrystallisation from
ethanol afforded 96a in a yield of 26%.
For 1H-NMR data see experiment 111.
Mass spec: [MS]: 308 m/z; expected 308 m/z [anhydride]
Experiment 111
Sulfonated methoxy-substituted phthalonitrile derivative (96a) (SG-339)
F
FF
NC
NC
OCH3
SO3H
C15H7F3N2O4SMol. Wt.: 368.29 g/mol
Following general procedure (G) 95a (0.07 g; 0.26 mmol) was stirred in TFA:H2SO4
(1:1) (8 ml) for 96 hr. Following work-up the crude yield was found to be 0.07 g
(0.19 mmol; 73%). The 1H-NMR showed this to be the sulfonated product.
1H–NMR: (400 MHz, C2D6CO): δ (ppm) = 4.02 (s; 3H; OCH3), 7.37 (dd; 3J =
8.8Hz; 1H; CHarom), 7.76 (dd; 3J = 8.8Hz; 1H; CHarom), 8.04 (s; 1H; CHarom).
Experiment 112
SG-317
F
FF
NC
NC
OCH3
OCH3
OCH3 SO3H
C17H11F3N2O6SMol. Wt.: 428.34 g/mol
Following general procedure (G) 95c (0.09 g; 0.26 mmol) was stirred in TFA:H2SO4
(4:1) (8 ml) overnight. The TLC showed the starting material spot had disappeared
251
so the reaction was quenched by pouring onto ice-water. A precipitate was formed
which was found to be an orange powder with a yield of 0.08 g. The 1H-NMR was
very similar to the starting material; however a mass spectrum was also obtained
which implied that this was the anhydride of the starting material as there was a peak
at 368 m/z. However, the filtrate was also extracted with ethyl acetate (×3), the
organic layers combined and dried over MgSO4 and the solvent evaporated. The
crude yield was found to be 0.02 g and the 1H-NMR showed no evidence of the
sulfonated product.
Mass spec: [MS]: 368 m/z; expected 368 m/z [anhydride]
Experiment 113
SG-348
F
FF
NC
NC
OCH3
OCH3
OCH3 SO3H
C17H11F3N2O6SMol. Wt.: 428.34 g/mol
Following general procedure (G) 95c (0.21 g; 0.59 mmol) was stirred in TFA:H2SO4
(4:1) (8 ml) for 96 hr. The reaction was worked up as usual and the.1H-NMR of the
crude product showed no evidence of the sulfonated product.
7.4.3 General procedure (H):
The desired methxoy-substituted phthalonitrile derivative (2 equiv.) and zinc acetate
dihydrate (1 equiv.) were crushed together using a pestle and mortar and transferred
to a pyrex test tube. This was inserted into a steel carousel which was placed on top
of a hotplate. The cap was screwed on to the test tube and the N2 tubing hooked up to
the carousel. The test tube was flushed with N2 for several minutes and then a
balloon filled to keep the reaction under N2, after which the tap was closed. The
reaction mixture was then heated to 190oC for 1.5 hr. The melt that formed was a
dark green in colour. The reaction was then allowed to cool down, acetone added and
252
the solution centrifuged. The resulting dark green solvent was then evaporated and
the product obtained.
Experiment 114
Dimethoxy-substituted phthalocyanine (97b) (SG-335)
N
NN
N
N
N
NN
H3CO
OCH3
OCH3
OCH3
OCH3
OCH3
OCH3
H3CO
F F
F
F
F F
F F
F F
F FZn
C64H36F12N8O8ZnMol. Wt.: 1338.39 g/mol
General procedure (H) was followed using 95b (0.16 g; 0.50 mmol) and zinc acetate
dihydrate (0.06 g; 0.26 mmol). The reaction mixture was heated to 190oC for 1.5 hr.
The melt that formed was a dark green in colour. The reaction was then allowed to
cool down, acetone added and the solution centrifuged. The resulting dark green
solvent was then evaporated and the product found to be a dark green solid with a
yield of 0.15 g (0.45 mmol; 90%). The 1H-NMR showed this to be identical to the
starting material, however the green colour is proof that the desired phthalocyanine
was formed.
SG-336:
General procedure (H) was followed using, 95b (0.14 g; 0.44 mmol) and zinc acetate
dihydrate (0.05 g; 0.22 mmol). The crude yield was found to be 0.16 g (0.48 mmol;
253
109%). Again the 1H-NMR showed this to be identical to the starting material,
however the green colour is proof that the desired phthalocyanine was formed.
1H–NMR: (400 MHz, CDCl3): δ (ppm) = 3.81 (s; 3H; OCH3), 3.88 (s; 3H; OCH3),
6.58 (d; 4J = 2.0Hz; 1H; CHarom), 6.62 (dd; 3J = 8.4Hz; 4J = 2.0Hz; 1H; CHarom), 7.15
(d; 3J = 8.4Hz; 1H; CHarom). 19F–NMR: (400 MHz, CDCl3/C6F6): δ (ppm) = -132.8 (q; J = 12Hz; 1F; CFarom), -
122.4 (q; J = 12Hz; 1F; CFarom), -106.0 (t; J = 12Hz; 1F; CFarom). 13C–NMR: (100 MHz, CDCl3): δ (ppm) = 55.7 (1C; OCH3), 55.9 (1C; OCH3), 99.1
(1C; CHarom), 105.4 (1C; CHarom), 132.0 (1C; CHarom), 158.2 (1C; Cq), 163.5 (1C;
Cq).
Experiment 115
Dimethoxy-substituted phthalocyanine (97a) (SG-349)
N
NN
N
N
N
NN
OCH3
OCH3
OCH3
H3CO
F F
F
F
F F
F F
F F
F FZn
C60H28F12N8O4ZnMol. Wt.: 1218.29 g/mol
General procedure (H) was followed using 95a (0.04 g; 0.15 mmol) and zinc acetate
dihydrate (0.02 g; 0.08 mmol). The reaction mixture was heated to 190oC for 2 hr.
The melt that formed was a dark green in colour. The reaction was then allowed to
254
cool down, acetone added and the solution centrifuged. The resulting dark green
solvent was then evaporated and the product found to be a dark green solid with a
yield of 0.03 g (0.10 mmol; 67%). The 1H-NMR showed this to be similar to the
starting material, however the green colour is proof that the desired phthalocyanine
was formed.
1H–NMR: (400 MHz, CDCl3): δ (ppm) = 3.89 (s; 3H; OCH3), 7.06 (dd; 3J = 6.8Hz;
4J = 2.4Hz; 2H; CHarom), 7.42 (dd; 3J = 6.8Hz; 4J = 2.0Hz; 2H; CHarom).
Experiment 116
SG-337
N
NN
N
N
N
NN
H3CO
OCH3SO3H
OCH3
OCH3
SO3H
OCH3
OCH3
HO3S
OCH3
H3CO
HO3S
F F
F
F
F F
F F
F F
F FZn
C64H36F12N8O20S4ZnMol. Wt.: 1658.64 g/mol
General procedure (H) was followed using 96b (0.04 g; 0.11 mmol) and zinc acetate
dihydrate (0.01 g; 0.06 mmol). The reaction was heated for 2 hr and the crude yield
was found to be 0.01 g. The 1H-NMR showed this to be similar to 96b, which means
the sulfonate group may have been lost, however the green colour is proof that a
phthalocyanine was formed. The sulfonated Pc was not formed.
255
Experiment 117
Sulfonated dimethoxy-substituted phthalocyanine (98b) (SG-338)
N
NN
N
N
N
NN
H3CO
OCH3SO3H
OCH3
OCH3
SO3H
OCH3
OCH3
HO3S
OCH3
H3CO
HO3S
F F
F
F
F F
F F
F F
F FZn
C64H36F12N8O20S4ZnMol. Wt.: 1658.64 g/mol
General procedure (G) was followed, using 97b (0.14 g; 0.11 mmol) and TFA:H2SO4
(4:1) (5 ml). The solution was stirred at R.T for 48 hr, when checked by TLC starting
material was still present so H2SO4 (~1 ml) was added and the solution allowed to
stir overnight. Following work-up the yield was found to be 0.10 g. The 1H-NMR
showed the desired product had been formed, however was not pure. The product
was still green in colour.
1H–NMR: (400 MHz, C2D6CO): δ (ppm) = 3.92 (s; 3H; OCH3), 3.93 (s; 3H; OCH3),
6.95 (s; 1H; CHarom), 7.86 (s; 1H; CHarom). 19F–NMR: (400 MHz, C2D6CO/C6F6): δ (ppm) = -133.2 (q; J = 12Hz; 1F; CFarom), -
122.5 (q; J = 12Hz; 1F; CFarom), -106.6 (t; J = 12Hz; 1F; CFarom).
256
7.5 Chapter 6: Microphotochemistry performed with selected
reactions
Experiment 118
4-(1,3-dioxoisoindolin-2-yl)butanoic acid (99a) (SG-16)
N
O
O CO2H
C12H11NO4Mol. Wt.: 233.22 g/mol
Phthalic anhydride (7.7 g, 52.0 mmol) and 4-aminobutanoic acid (5.4 g, 52.0 mmol)
were heated in DMF to 150oC for 1.5 hr. Once the solution had cooled to ~50oC,
acetone (10 ml) was added and the resulting solution poured onto ice. A precipitate
was observed, which was filtered by vacuum filtration and washed with distilled
H2O. The product was obtained as a light yellow solid with a yield of 11.9 g (52.0
mmol; 98 %).
1H–NMR: (400 MHz, C2D6CO): δ (ppm) = 2.01 (m; 2H; CH2), 2.44 (t; 3J = 7.0 Hz;
2H; CH2), 3.77 (t; 3J = 7.0 Hz; 2H; CH2), 7.88 (m; 4H; CHarom). 13C–NMR: (100 MHz, C2D6CO): δ (ppm) = 24.6 (1C; CH2), 32.5 (1C; CH2), 38.3
(1C; CH2), 123.7 (2C; CHarom), 133.2 (2C; Cq), 134.9 (2C; CHarom), 168.9 (2C,
C=O).
CAS No.: 3130-75-4
257
Experiment 119
(S)-2-(1,3-dioxoisoindolin-2-yl)pentanedioic acid (99b) (SG-141)
N
O
O CO2H
CO2H
C13H11NO6Mol. Wt.: 277.23 g/mol
Phthalic anhydride (5.0 g; 34.0 mmol) and L-glutamic acid (5.0 g, 34.0 mmol) were
heated in DMF to 150oC for 1.5 hr. Following addition of acetone (10 ml), the
product did not precipitate as expected when poured over ice, so the water was
evaporated and a brown oil obtained. A 1H-NMR showed this was the desired
product; however some phthalic anhydride was also present. To purify, the oil was
dissolved in CDCl3 and hexane added. After sonication, a colourless solid was
observed to precipitate which was filtered and dried. The yield was found to be 12.4
g (43.8 mmol; 129%). This high yield can be explained by the presence of the
starting material. This was nevertheless used in the photoreactions. To remove the
phthalic anhydride, a portion of this (0.05 g) was then recrystallised from distilled
H2O and the NMR showed this was solely the pure product. The yield was found to
be 0.04 g (80%). [Overall yield: (0.15 mmol; 0.4%)]. The product was a colourless
powder.
1H–NMR: (400 MHz, CDCl3): δ (ppm) = 2.16 (t; 3J = 7.6Hz; 2H; CH2), 2.28 (m;
1H; CH2), 2.41 (m; 1H; CH2), 4.71 (m; 1H; CHasym), 7.57 (m; 2H; CHarom), 7.67 (m;
2H; CHarom). 13C–NMR: (100 MHz, CDCl3): δ (ppm) = 23.8 (1C; CH2), 30.5 (1C; CH2), 51.1 (1C;
CHasym), 123.1 (2C; CHarom), 131.5 (2C; CHarom), 133.9 (2C; Cq), 167.3 (2C; 2 ×
C=O), 170.5 (1C; C=O), 173.9 (1C; C=O).
CAS No.: 340-90-9
258
7.5.1 General Procedure (I):
2-phthalimidobenzoic acid (3.0 mmol), desired benzyl ester salt (3.0 mmol) and
DCM (30 ml) were placed in a 100 ml round bottom flask. TEA (3.0 mmol) was
added and the solution cooled to 0oC in an ice bath. EDC (3.0 mmol) was then added
and the solution stirred at 0oC for 1 hr, and then at room temperature overnight. The
solvent was evaporated and the residue partitioned between ethyl acetate and water.
The organic layer was washed with water (× 3), dilute HCl (× 2), dilute Na2CO3 (×
2), and brine (× 1). This was then dried over MgSO4, filtered and the solvent
evaporated. A 1H-NMR was obtained to confirm the expected product had been
formed.
A hydrogenisation was then performed by dissolving the product (2.0 mmol) in
methanol (50 ml) and degassing under argon for ~15 min. During this time,
Pd/Charcoal (0.50 g) was added. A balloon filled with H2 gas was then put in place
so the solution was under H2 in a closed system while being stirred overnight. The
mixture was then filtered through a celite patch, the solvent evaporated and a 1H-
NMR obtained.
Experiment 120a
(S)-benzyl 2-(2-(1,3-dioxoisoindolin-2-yl)benzamido)propanoate and (S)-2-(2-
(1,3-dioxoisoindolin-2-yl)benzamido)propanoic acid (100a and 100b) (SG-149
and SG-151)
N
O
O
NHH3C
OO
O
C25H20N2O5Mol. Wt.: 428.44 g/mol
N
ONH CH3
OOH
O
O
C18H14N2O5Mol. Wt.: 338.31 g/mol
General procedure (I) was followed using 2-phthalimidobenzoic acid (0.8 g; 3.01
mmol), L-alanine-benzylester-p-toluenesulfonate salt (1.1 g; 3.0 mmol), TEA (0.3 g;
3.15 mmol) and EDC (0.6 g, 3.03 mmol). The solution was stirred for 48 hr and
259
following work-up, the 1H-NMR confirmed the product had been formed as a clear
foamy oil with a yield of 0.9 g (2.02 mmol; 67%). The hydrogenisation was then
carried out using the phenyl ester 100a (0.8 g; 1.97 mmol). A 1H-NMR showed the
desired product was present however; a small amount of the methyl ester had also
been formed. This was purified by dissolving the product in ethyl acetate (~20 ml)
and extracting with saturated NaHCO3 (2 × 20 ml). The aqueous layer was then
dropped onto acidified ice and the desired product precipitated. This was filtered,
washed with water and dried. A 1H-NMR showed this was the pure product and the
yield was found to be 0.5 g (1.56 mmol; 79%). [Overall yield = 52%]. The product
was a colourless powder.
100b: 1H–NMR: (400 MHz, CDCl3): δ (ppm) = 1.43 (d; 3J = 7.2Hz; 3H; CH3), 4.59 (m;
1H; CHasym), 6.59 (br.d; 3J = 6.8Hz; 1H; NH), 7.40 (dd; 3J = 7.6Hz; 4J = 1.2Hz; 1H;
CHarom), 7.53 (ddd; 3J = 7.6Hz; 4J = 1.2Hz; 1H; CHarom), 7.63 (ddd; 3J = 7.6Hz; 4J =
1.2Hz; 1H; CHarom), 7.70 (dd; 3J = 7.6Hz; 4J = 1.2Hz; 1H; CHarom), 7.76 (m; 2H;
CHarom), 7.92 (m; 2H; CHarom). 13C–NMR: (100 MHz, CDCl3): δ (ppm) = 17.9 (1C; CH3), 48.5 (1C; CHasym), 24.8
(1C; CH), 124.0 (2C; Cq), 128.5 (1C; CHarom), 129.3 (1C; CHarom), 129.8 (1C; Cq),
130.0 (1C; CHarom), 131.8 (1C; CHarom), 132.0 (2C; CHarom), 133.6 (1C; Cq), 134.6
(2C; CHarom), 167.0 (1C; C=O), 167.7 (1C; C=O), 176.2 (2C; C=O).
CAS No.: 330434-07-6
260
Experiment 120b
(S)-benzyl 2-(2-(1,3-dioxoisoindolin-2-yl)benzamido)propanoate and (S)-2-(2-
(1,3-dioxoisoindolin-2-yl)benzamido)propanoic acid (100a and 100b) (SG-214
and SG-217)
N
O
O
NHH3C
OO
O
C25H20N2O5Mol. Wt.: 428.44 g/mol
N
ONH CH3
OOH
O
O
C18H14N2O5Mol. Wt.: 338.31 g/mol
General procedure (I) was followed, using 2-phthalimidobenzoic acid (0.80 g; 3.00
mmol), L-alanine-benzylester-p-toluenesulfonate salt (1.05 g; 3.00 mmol), TEA
(0.30 g; 3.01 mmol) and EDC (0.58 g, 3.00 mmol). The 1H-NMR confirmed the
product had been formed as a yellow foamy solid with a yield of 0.91 g (2.12 mmol;
71%). The hydrogenisation was then carried out using the phenyl ester 100a (0.89 g;
2.07 mmol). A slight modification was applied to this reaction in that ethyl acetate
was used as the solvent instead of methanol, which eliminated the problem of the
methyl ester being formed along with the desired product. The 1H-NMR showed this
to be the pure product and the yield was found to be 0.63 g (1.86 mmol; 90%).
[Overall yield = 62%]. The product was a colourless foamy solid.
100a: 1H–NMR: (400 MHz, CDCl3): δ (ppm) = 1.40 (d; 3J = 7.2Hz; 3H; CH3), 4.64 (m;
1H; CHasym), 5.11 (d; 3J = 12.4Hz; 1H; CH2), 5.15 (d; 3J = 12.4Hz; 1H; CH2), 6.63
(br.d; 3J = 7.6Hz; 1H; NH), 7.29-7.38 (m; 5H; CHarom), 7.40 (dd; 3J = 7.6Hz; 4J =
1.2Hz; 1H; CHarom), 7.51 (ddd; 3J = 7.6Hz; 4J = 1.2Hz; 1H; CHarom), 7.62 (ddd; 3J =
7.6Hz; 4J = 1.6Hz; 1H; CHarom), 7.70 (dd; 3J = 7.6Hz; 4J = 1.6Hz; 1H; CHarom), 7.76
(m; 2H; CHarom), 7.92 (m; 2H; CHarom).
100b:
For 1H-NMR data see experiment 120a.
261
Experiment 121
(S)-benzyl 2-(2-(1,3-dioxoisoindolin-2-yl)benzamido)-4-methylpentanoate and
(S)-2-(2-(1,3-dioxoisoindolin-2-yl)benzamido)-4-methylpentanoic acid (101a and
101b) (SG-145 and SG-150)
N
O
O
NH
OO
O
C28H26N2O5Mol. Wt.: 470.52 g/mol
N
O
O
NH
OHO
O
C21H20N2O5Mol. Wt.: 380.39 g/mol
General procedure (I) was followed, using 2-phthalimidobenzoic acid (0.8 g; 3.0
mmol), L-leucine-benzylester toluene-4-sulfonate salt (1.2 g; 3.01 mmol), TEA (0.3
g; 3.0 mmol) and EDC (0.6 g, 3.0 mmol). The 1H-NMR confirmed the product had
been formed as a pale yellow oil with a yield of 1.1 g (2.26 mmol; 75%). The
hydrogenisation was then carried out using the phenyl etser 101a (1.0 g; 2.03 mmol).
A 1H-NMR showed the desired product was present however, a small amount of the
methyl ester had also been formed. This was purified by dissolving the product in
ethyl acetate (~20 ml) and extracting with saturated NaHCO3 (2 × 20 ml). The
aqueous layer was then dropped onto acidified ice and the desired product
precipitated. This was filtered, washed with water and dried. A 1H-NMR showed this
was the pure product and the yield was found to be 0.4 g (1.02 mmol; 50%). [Overall
yield = 34%].The product was a colourless powder.
101a: 1H–NMR: (400 MHz, CDCl3): δ (ppm) = 0.84 (t; 3J = 6.0Hz; 6H; 2 × CH3), 1.54 (m;
1H; CH), 1.59-1.71 (m; 2H; CH2), 4.70 (m; 1H; CHasym) 5.10 (s; 2H; CH2), 6.40
(br.d; 3J = 8.4Hz; 1H; NH), 7.32 (m; 5H; CHarom), 7.39 (dd; 3J = 8.0Hz; 4J = 1.2Hz;
1H; CHarom), 7.51 (ddd; 3J = 7.6Hz; 4J = 1.2Hz; 1H; CHarom), 7.61 (ddd; 3J = 7.6Hz;
262
4J = 1.6Hz; 1H; CHarom), 7.68 (dd; 3J = 7.6Hz; 4J = 1.6Hz; 1H; CHarom), 7.76 (m; 2H;
CHarom), 7.90 (m; 2H; CHarom).
101b: 1H–NMR: (400 MHz, CDCl3): δ (ppm) = 0.87 (t; 3J = 6.6Hz; 6H; 2 × CH3), 1.52-
1.60 (m; 1H; CH), 1.61-1.71 (m; 2H; CH2), 4.60 (m; 1H; CHasym) 6.50 (br.d; 3J =
8.0Hz; 1H; NH), 7.38 (dd; 3J = 7.6Hz; 4J = 0.8Hz; 1H; CHarom), 7.52 (ddd; 3J =
7.6Hz; 4J = 0.8Hz; 1H; CHarom), 7.61 (ddd; 3J = 7.6Hz; 4J = 1.2Hz; 1H; CHarom), 7.69
(dd; 3J = 7.6Hz; 4J = 1.2Hz; 1H; CHarom), 7.74 (m; 2H; CHarom), 7.90 (m; 2H;
CHarom). 13C–NMR: (100 MHz, CDCl3): δ (ppm) = 21.7 (1C; CH3), 22.9 (1C; CH3), 24.8 (1C;
CH), 40.9 (1C; CH2), 51.0 (1C; CHasym), 123.9 (1C; Cq), 128.5 (1C; CHarom), 129.4
(1C; CHarom), 129.7 (1C; Cq), 130.0 (1C; CHarom), 131.7 (1C; CHarom), 132.0 (2C; 2 ×
CHarom), 134.0 (1C; Cq), 134.5 (2C; 2 × CHarom), 147.9 (1C; Cq), 167.1 (1C; C=O),
167.7 (1C; C=O), 170.0 (1C; C=O), 176.4 (1C; C=O).
CAS No.: 330434-09-8
7.5.2 General Procedure (J):
NMP (0.38 mmol) was dissolved in 5 ml of acetone. The addition partner (1.13
mmol) was added to K2CO3 (0.57 mmol) and dissolved in 5 ml of distilled H2O.
These solutions were then added together in a conical flask and made up to 25 ml
using a mixture of acetone/water (50:50). This solution was sonicated for 5 min and
then degassed with a slow stream of N2 for ~20 min. The microreactor was prepared
by pumping the pre-sonicated mobile phase of acetone/water (50:50) through it until
all air bubbles had been removed. The solution (10 ml) was then taken up in the
syringe and any air bubbles expelled and connected to the syringe pump. The flow
rate was then set, the syringe pump and the lamps (λ = 300±20 nm) above the
microreactor were switched on and the irradiated solution collected in a round-
bottomed flask. During the reaction, the reactor was kept cool by pumping cold water
through the second cooling channel. When the syringe was empty, the syringe pump
and the lamps were switched off simultaneously. The syringe was filled with the
mobile phase and replaced on the syringe pump which was then turned on
263
simultaneously with the lamps. When the reaction was complete, acetone was
removed by rotary evaporation at ~50oC and the remaining solution was extracted
with DCM (3 × 20 ml). The two layers were separated (organic → bottom layer,
aqueous → top layer) and the organic layer washed with saturated NaHCO3 (2 × 20
ml) and then with saturated NaCl (2 × 20 ml). The organic layer was collected and
dried over MgSO4, filtered by gravity filtration and the DCM evaporated from the
filtrate by rotary evaporation at ~40oC. A 1H-NMR was obtained for the crude
product. There was not enough product obtained to perform column chromatography.
Experiment 122
Comparison of Experiment 4
3-benzyl-3-hydroxy-2-methylisoindolin-1-one (67a) (SG-204)
N
O
CH3
HO
C16H15NO2Mol. Wt.: 253.3 g/mol
General procedure (J) was followed, with the slight variation of doubling amounts
used and dissolving in 50 ml instead of the usual 25 ml, using NMP (0.12 g; 0.75
mmol), phenylacetic acid (0.31 g, 2.26 mmol) and K2CO3 (0.16 g, 1.13 mmol). The
flow rate used was 0.12 ml/min; residence time: 14 min. The composition of NMP to
product was calculated from the 1H-NMR to be 75:25.
For 1H-NMR data see experiment 4.
264
Experiment 123
Comparison of Experiment 4
3-benzyl-3-hydroxy-2-methylisoindolin-1-one (67a) (SG-205)
N
O
CH3
HO
C16H15NO2Mol. Wt.: 253.3 g/mol
General procedure (J) was followed using the same stock solution as used in
experiment 122. The flow rate used was 0.08 ml/min; residence time: 21 min. The
composition of NMP to product was calculated from the 1H-NMR to be 60:40.
For 1H-NMR data see experiment 4.
Experiment 124
Comparison of Experiment 4
3-benzyl-3-hydroxy-2-methylisoindolin-1-one (67a) (SG-206)
N
O
CH3
HO
C16H15NO2Mol. Wt.: 253.3 g/mol
General procedure (J) was followed using the same stock solution as used in
experiment 122. The flow rate used was 0.06 ml/min; residence time: 28 min. The
composition of NMP to product was calculated from the 1H-NMR to be 58:42.
For 1H-NMR data see experiment 4.
265
Experiment 125
Comparison of Experiment 4
3-benzyl-3-hydroxy-2-methylisoindolin-1-one (67a) (SG-195)
N
O
CH3
HO
C16H15NO2Mol. Wt.: 253.3 g/mol
The general procedure (J) was followed using the same stock solution as used in
experiment 126. The flow rate used was 0.05 ml/min; residence time: 33 min 36sec.
The composition of NMP to product was calculated from the 1H-NMR to be 41:59.
For 1H-NMR data see experiment 4.
Experiment 126
Comparison of Experiment 4
3-benzyl-3-hydroxy-2-methylisoindolin-1-one (67a) (SG-194)
N
O
CH3
HO
C16H15NO2Mol. Wt.: 253.3 g/mol
General procedure (J) was followed using NMP (0.06 g, 0.37 mmol), phenylacetic
acid (0.15, 1.13 mmol) and K2CO3 (0.08 g, 0.56 mmol). The flow rate used was 0.04
ml/min; residence time: 42 min. The conversion was found to be 100% and the yield
was found to be 0.04 g (0.15 mmol; 100%). The 1H-NMR showed this to be the
desired pure product.
For 1H-NMR data see experiment 4.
266
Experiment 127a-c
Comparison of Experiment 64
3-(2-iodobenzyl)-3-hydroxy-2-methylisoindolin-1-one (82a) (SG-103)
N
O
CH3
HO
C16H14INO2Mol. Wt.: 379.19 g/mol
I
General procedure (J) was followed, with slight variation, using NMP (0.06 g, 0.39
mmol), 2-iodophenylacetic acid (0.3 g, 1.13 mmol) and K2CO3 (0.1 g, 0.56 mmol).
The reactant solution was made up to 25 ml and was pumped through the
microreactor in its entirety. The flow rate used was varied 3 times throughout the
reaction and all 3 fractions were collected and TLCs performed. In each the starting
material was visible. The fractions were then worked up in the usual way, 1H-NMRs
obtained and the ratio of NMP to product calculated.
a) Fraction 1 used a flow rate of 0.249 ml/min; residence time: 6 min 42 sec. The
ratio was 95:5.
b) Fraction 2 used a flow rate of 0.162 ml/min; residence time: 10 min 24 sec. The
ratio was 92:8.
c) Fraction 3 used a flow rate of 0.129 ml/min; residence time: 14 min. The ratio was
90:10.
For 1H-NMR data see experiment 64.
267
Experiment 128
Comparison of Experiment 64
3-(2-iodobenzyl)-3-hydroxy-2-methylisoindolin-1-one (82a) (SG-168)
N
O
CH3
HO
C16H14INO2Mol. Wt.: 379.19 g/mol
I
General procedure (J) was followed, with slight variation, using NMP (0.12 g, 0.75
mmol), 2-iodophenylacetic acid (0.59, 2.25 mmol) and K2CO3 (0.16 g, 1.13 mmol).
The flow rate used was 0.08 ml/min; residence time: 21 min. The ratio of NMP to
product was calculated from the 1H-NMR to be 86:14.
For 1H-NMR data see experiment 64.
Experiments 129 and 130
Comparison of Experiment 64
3-(2-iodobenzyl)-3-hydroxy-2-methylisoindolin-1-one (82a) (SG-174)
N
O
CH3
HO
C16H14INO2Mol. Wt.: 379.19 g/mol
I
General procedure (J) was followed using NMP (0.06 g, 0.39 mmol), 2-
iodophenylacetic acid (0.30 g, 1.14 mmol) and K2CO3 (0.08 g, 0.57 mmol). The flow
rate was initially set at 0.01 ml/min; residence time: 2 hr 48 min. This fraction was
collected and worked up as usual and the ratio of NMP to product was calculated
from the 1H-NMR to be 77:23.
268
The flow rate was then changed to 0.04 ml/min; residence time: 42 min, the reaction
continued and the second fraction collected and worked up. This time the ratio of
NMP to product was calculated from the 1H-NMR to be 81:19.
For 1H-NMR data see experiment 64.
Experiment 131
Comparison of Experiment 5
3-(4-methylbenzyl)-3-hydroxy-2-methylisoindolin-1-one (67b) (SG-252)
N
O
CH3
HO CH3
C17H17NO2Mol. Wt.: 267.32 g/mol
General procedure (J) was followed using NMP (0.06 g; 0.38 mmol), p-tolylacetic
acid (0.17 g, 1.13 mmol) and K2CO3 (0.08 g, 0.56 mmol). The flow rate was set at
0.007 ml/min; residence time: 4 hr. The 1H-NMR showed the product was formed in
its pure state. The yield was found to be 0.04 g (0.14 mmol; 93%).
For 1H-NMR data see experiment 5.
Experiment 132
Comparison of Experiment 8
3-(4-fluorobenzyl)-3-hydroxy-2-methylisoindolin-1-one (67e) (SG-253)
N
O
CH3
HO F
C16H14FNO2Mol. Wt.: 271.29 g/mol
269
General procedure (J) was followed using NMP (0.06 g; 0.38 mmol), 4-
fluorophenylacetic acid (0.17 g, 1.13 mmol) and K2CO3 (0.08 g, 0.57 mmol). The
flow rate was set at 0.007 ml/min; residence time: 4 hr. The 1H-NMR showed the
product was formed in its pure state. The yield was found to be 0.02 g (0.08 mmol;
53%).
For 1H-NMR data see experiment 8.
Experiment 133
Comparison of Experiment 10
3-(3,4-dichlorobenzyl)-3-hydroxy-2-methylisoindolin-1-one (67 g) (SG-257)
N
O
CH3
HO Cl
Cl
C16H13Cl2NO2Mol. Wt.: 322.19 g/mol
General procedure (J) was followed using NMP (0.06 g; 0.38 mmol), 3,4-
dichlorophenylacetic acid (0.23 g, 1.13 mmol) and K2CO3 (0.08 g, 0.56 mmol). The
flow rate was set at 0.009 ml/min; residence time: 3 hr. The NMR showed the
product was formed in its pure state. The yield was found to be 0.04 g (0.14 mmol;
93%).
For 1H-NMR data see experiment 10.
270
Experiment 134
Comparison of Experiment 11
3-(2-bromobenzyl)-3-hydroxy-2-methylisoindolin-1-one (67h) (SG-260)
N
O
CH3
HO
C16H14BrNO2Mol. Wt.: 332.19
Br
General procedure (J) was followed using NMP (0.06 g; 0.38 mmol), 2-
bromophenylacetic acid (0.24 g, 1.14 mmol) and K2CO3 (0.08 g, 0.56 mmol). The
flow rate was set at 0.006 ml/min; residence time: 4 hr 40 min. The NMR showed the
product was formed with some minor impurities present. The crude product was
purified by adding a small amount of acetone to dissolve the impurities and then
removing the solvent. The 1H-NMR obtained showed this to be the pure product, and
the yield was found to be 0.04 g (0.09 mmol; 60%).
For 1H-NMR data see experiment 11.
Experiment 135
Comparison of Experiment 17
3-(4-methylbenzyl)-3-hydroxyisoindolin-1-one (68a) (SG-290)
NH
O
HO CH3
C16H15NO2Mol. Wt.: 253.3 g/mol
General procedure (J) was followed, with slight variation, using phthalimide (0.06 g;
0.38 mmol), p-tolylacetic acid (0.17 g, 1.13 mmol) and K2CO3 (0.08 g, 0.56 mmol).
The flow rate was set at 0.014 ml/min; residence time: 2 hr. The product was found
271
to have a yield of 0.04 g, (0.15 mmol; 97%). The 1H-NMR showed the desired
product had been formed.
For 1H-NMR data see experiment 17.
Experiment 136
Comparison of Experiment 19
3-(4-fluorobenzyl)-3-hydroxyisoindolin-1-one (68b) (SG-288)
NH
O
HO F
C15H12FNO2Mol. Wt.: 257.26 g/mol
General procedure (J) was followed, with slight variation, using phthalimide (0.06 g;
0.37 mmol), 4-fluorophenylacetic acid (0.17 g, 1.13 mmol) and K2CO3 (0.08 g, 0.56
mmol). The flow rate was set at 0.014 ml/min; residence time: 2 hr. The product was
found to have a yield of 0.04 g, (0.15 mmol; 100%). The 1H-NMR showed the
desired product had been formed.
For additional 1H-NMR data see experiment 19.
19F–NMR: (400 MHz, C2D6CO/C6F6): δ (ppm) = -118.5 (s; 1F; CF).
272
Experiment 137
Comparison of Experiment 42
N-((S)-1-(Like and Unlike-1-hydroxy-2-methyl-3-oxoisoindolin-1-yl)-2-
methylpropyl)acetamide (78c) (SG-189)
N CH3
O
HONH
O
C15H20N2O3Mol. Wt.: 276.33 g/mol
N CH3
O
HONH
O
General procedure (J) was followed using NMP (0.06 g, 0.39 mmol), acetyl-valine
(0.18 g, 1.13 mmol) and K2CO3 (0.08 g, 0.56 mmol). The flow rate was set at 0.04
ml/min; residence time: 42 min. The 1H-NMR showed the crude product to be
mainly NMP, however both isomers of the product were also present. The
composition of NMP to product was calculated from the 1H-NMR to be 96:4. and the
ratio of the isomers was found to be 62:38.
For 1H-NMR data see experiment 42.
Experiment 138
Comparison of Experiment 42
N-((S)-1-(Like and Unlike-1-hydroxy-2-methyl-3-oxoisoindolin-1-yl)-2-
methylpropyl)acetamide (78c) (SG-215)
N CH3
O
HONH
O
C15H20N2O3Mol. Wt.: 276.33 g/mol
N CH3
O
HONH
O
General procedure (J) was followed using NMP (0.06 g, 0.38 mmol), acetyl-valine
(0.18 g, 1.13 mmol) and K2CO3 (0.08 g, 0.56 mmol). The flow rate was set at 0.008
273
ml/min; residence time: 3 hr 30 min. The composition of NMP to product was
calculated from the 1H-NMR to be 58:42. The ratio of the isomers was calculated
from the 1H-NMR to be 62:38.
For 1H-NMR data see experiment 42.
Experiment 139
Comparison of Experiment 44
N-(1-(1-hydroxy-2-methyl-3-oxoisoindolin-1-yl)-3-methylbutyl)acetamide (78d)
(SG-171)
N
O
CH3
HONH
O
C16H22N2O3Mol. Wt.: 290.36 g/mol
General procedure (J) was followed using NMP (0.12 g, 0.75 mmol), acetyl-leucine
(0.39, 2.25 mmol) and K2CO3 (0.16 g, 1.13 mmol). The flow rate used was 0.08
ml/min; residence time: 21 min. The composition of NMP to product was calculated
from the 1H-NMR to be 74:26. The ratio of the isomers was calculated from the 1H-
NMR to be 46:54.
For 1H-NMR data see experiment 44.
274
Experiment 140
Comparison of Experiment 44
N-(1-(1-hydroxy-2-methyl-3-oxoisoindolin-1-yl)-3-methylbutyl)acetamide (78d)
(SG-191)
N
O
CH3
HONH
O
C16H22N2O3Mol. Wt.: 290.36 g/mol
General procedure (J) was followed using NMP (0.06 g, 0.37 mmol), acetyl-leucine
(0.20, 1.13 mmol) and K2CO3 (0.08 g, 0.56 mmol). The flow rate used was 0.04
ml/min; residence time: 42 min. The composition of NMP to product was calculated
from the 1H-NMR to be 82:18. The ratio of isomers was calculated from the 1H-
NMR to be 43:57.
For 1H-NMR data see experiment 44.
Experiment 141
Comparison of Experiment 46
N-((1S,2S) and (1S,2R)-1-((R) and (S)-1-hydroxy-2-methyl-3-oxoisoindolin-1-yl)-
2-methylbutyl)acetamide (78e) (SG-170)
N
O
CH3
HONH O
C16H22N2O3Mol. Wt.: 290.36 g/mol
N
O
CH3
HONH O
N
O
CH3
HONH O
N
O
CH3
HONH O
General procedure (J) was followed using NMP (0.06 g, 0.40 mmol), acetyl-
isoleucine (0.20 g, 1.13 mmol) and K2CO3 (0.08 g, 0.56 mmol). The flow rate used
275
was 0.08 ml/min; residence time: 21 min. TLC showed the product was formed,
however some NMP was also present showing that the residence time was not
sufficient for the reaction to go to completion. The 1H-NMR obtained confirmed the
product was formed and the ratio of NMP to product was calculated to be 73:27. The 1H-NMR also confirmed that four diastereoisomers were formed in a ratio of
26:26:26:22.
For additional 1H-NMR data see experiment 46.
1H–NMR: (400 MHz, C2D6CO): δ (ppm) =
Selected peaks for CH(NH):
4.48 (dd; 3J = 10.0Hz; 3J = 6.0Hz; 1H; CH), 4.53 (dd; 3J = 9.2Hz; 3J = 3.6Hz; 1H;
CH), 4.67 (dd; 3J = 7.2Hz; 3J = 3.2Hz; 1H; CH), 4.69 (dd; 3J = 6.8Hz; 3J = 2.8Hz;
1H; CH).
Experiment 142
Comparison of Experiment 50
tert-butyl (S)-1-(Like and Unlike- 1-hydroxy-2-methyl-3-oxoisoindolin-1-
yl)ethylcarbamate (78i) (SG-192)
N
O
CH3
HONH O
O
C16H22N2O4Mol. Wt.: 306.36 g/mol
N
O
CH3
HONH O
O
General procedure (J) was followed using NMP (0.06 g, 0.38 mmol), N-(tert-
butoxycarbonyl)-L-alanine (0.21, 1.13 mmol) and K2CO3 (0.08 g, 0.57 mmol). The
flow rate used was 0.04 ml/min; residence time: 42 min. The composition of NMP to
product was calculated from the 1H-NMR to be 68:32. The ratio of isomers could not
be calculated from the 1H-NMR.
For 1H-NMR data see experiment 50.
276
Experiment 143
Comparison of Experiment 50
tert-butyl (S)-1-(Like and Unlike- 1-hydroxy-2-methyl-3-oxoisoindolin-1-
yl)ethylcarbamate (78i) (SG-199)
N
O
CH3
HONH O
O
C16H22N2O4Mol. Wt.: 306.36 g/mol
N
O
CH3
HONH O
O
General procedure (J) was followed using NMP (0.06 g, 0.38 mmol), N-(tert-
butoxycarbonyl)-L-alanine (0.21, 1.13 mmol) and K2CO3 (0.08 g, 0.57 mmol). The
flow rate used was 0.01 ml/min; residence time: 2 hr 48 min. The composition of
NMP to product was calculated from the 1H-NMR to be 7:93. The ratio of isomers
was calculated from the 1H-NMR to be 56:44.
For 1H-NMR data see experiment 50.
Experiment 144
Comparison of Experiment 52
tert-butyl (S)-1-(Like and Unlike-1-hydroxy-2-methyl-3-oxoisoindolin-1-yl)-2-
phenylethylcarbamate (78j) (SG-193)
N
O
CH3
HONH O
O
C22H26N2O4Mol. Wt.: 382.45 g/mol
N
O
CH3
HONH O
O
General procedure (J) was followed using NMP (0.06 g, 0.38 mmol), N-(tert-
butoxycarbonyl)-L-phenylalanine (0.30, 1.13 mmol) and K2CO3 (0.08 g, 0.57 mmol).
277
The flow rate used was 0.04 ml/min; residence time: 42 min. The composition of
NMP to product was calculated from the 1H-NMR to be 72:28. The ratio of isomers
was calculated from the 1H-NMR to be 24:76.
For 1H-NMR data see experiment 52.
Experiment 145
Comparison of Experiment 52
tert-butyl (S)-1-(Like and Unlike-1-hydroxy-2-methyl-3-oxoisoindolin-1-yl)-2-
phenylethylcarbamate (78j) (SG-212)
N
O
CH3
HONH O
O
C22H26N2O4Mol. Wt.: 382.45 g/mol
N
O
CH3
HONH O
O
General procedure (J) was followed using NMP (0.06 g, 0.38 mmol), N-(tert-
butoxycarbonyl)-L-phenylalanine (0.30, 1.13 mmol) and K2CO3 (0.08 g, 0.56 mmol).
The flow rate used was 0.01 ml/min; residence time: 2 hr 48 min. The composition of
NMP to product was calculated from the 1H-NMR to be 47:53. The ratio of isomers
was calculated from the 1H-NMR to be 28:72.
For 1H-NMR data see experiment 52.
7.5.3 General Procedure (J1):
As in General Procedure (J), with the variation of using TFPN (0.08 g; 0.38 mmol)
and 1,3,5-Trimethoxybenzene (0.19 g; 1.13 mmol). DCM was used as the sole
solvent and work-up consisted of removing the DCM by rotary evaporation.
278
Experiment 146
Comparison of Experiment 106
Trimethoxy-substituted phthalonitrile derivative (95c) (SG-314)
F
FF
NC
NC
OCH3
OCH3
OCH3
C17H11F3N2O3Mol. Wt.: 348.28 g/mol
General procedure (J1) was followed using TFPN (0.08 g; 0.38 mmol) and 1,3,5-
trimethoxybenzene (0.19 g; 1.13 mmol). The flow rate was set at 0.007 ml/min;
residence time: 4 hr. The crude yield was found to be 0.10 g. Both the 1H and 19F
NMR spectra showed this to be starting material.
Experiment 147
Comparison of Experiment 106
Trimethoxy-substituted phthalonitrile derivative (95c) (SG-315)
F
FF
NC
NC
OCH3
OCH3
OCH3
C17H11F3N2O3Mol. Wt.: 348.28 g/mol
General procedure (J1) was followed using TFPN (0.08 g; 0.38 mmol) and 1,3,5-
trimethoxybenzene (0.19 g; 1.14 mmol). The flow rate was set at 0.002 ml/min;
residence time: 14 hr. The crude yield was found to be 0.10 g. Both the 1H and 19F
NMR spectra showed this to be mainly starting material, however there was also
some product present. The ratio of TFPN to product was calculated from the 19F-
NMR to be 82:18.
For 1H-NMR data see experiment 106.
279
Experiment 148
Comparison of Experiment 106
Trimethoxy-substituted phthalonitrile derivative (95c) (SG-320)
F
FF
NC
NC
OCH3
OCH3
OCH3
C17H11F3N2O3Mol. Wt.: 348.28 g/mol
General procedure (J1) was followed, with slight variation, using TFPN (0.02 g; 0.08
mmol) and 1,3,5-trimethoxybenzene (0.04 g; 0.23 mmol). The flow rate was set at
0.002 ml/min; residence time: 14 hr. The crude yield was found to be 0.02 g. Both
the 1H and 19F-NMR spectra showed this to be mainly product, however there was
also some starting material remaining. The ratio of TFPN to product was calculated
from the 19F-NMR to be 16.84.
For 1H-NMR data see experiment 106.
Experiment 149
Comparison of Experiment 106
Trimethoxy-substituted phthalonitrile derivative (95c) (SG-326)
F
FF
NC
NC
OCH3
OCH3
OCH3
C17H11F3N2O3Mol. Wt.: 348.28 g/mol
General procedure (J1) was followed, with slight variation, using TFPN (0.02 g; 0.11
mmol) and 1,3,5-trimethoxybenzene (0.04 g; 0.21 mmol). The flow rate was set at
0.001 ml/min; residence time: 28 hr. The crude yield was found to be 0.06 g. Both
the 1H and 19F NMR spectra showed this to be mainly product, however there was
280
also some starting material remaining. The ratio of TFPN to product was calculated
from the 19F-NMR to be 39.61.
For 1H-NMR data see experiment 106.
7.5.4 General Procedure (K):
The desired phthalimide (1.50 mmol) was dissolved in 10 ml of acetone and K2CO3
(0.75 mmol) was dissolved in 10 ml of distilled H2O. These two solutions were
sonicated separately before being mixed together, transferred to a 100 ml Schlenk
flask and sonicated again. The reaction was then carried out as in general procedure
(A) for photoreactions in solution.
Experiment 150
9b-hydroxy-1, 2, 3, 9b-tetrahydro-pyrrolo[2,1-a]isoindol-5-one (102) (SG-156)
N
O
HO
C11H11NO2Mol. Wt.: 189.21 g/mol
General procedure (K) was followed using 99a (0.3 g, 1.50 mmol) and K2CO3 (0.1 g,
0.85 mmol). After 5.5 hr the TLC showed the product was formed. The solution was
clear and yellow at this point. The product was found to be a yellow-brown solid and
the 1H-NMR obtained confirmed this was the pure product. The yield was found to
be 0.2 g (1.23 mmol, 82%).
1H–NMR: (400 MHz, C2D6CO): δ (ppm) = 1.54 (m; 1H; CH2), 2.30 (m; 2H; CH2),
2.57 (m; 1H; CH2), 3.35 (m; 1H; CH2), 3.61 (m; 1H; CH2), 5.26 (br.s; 1H; OH), 7.50
(m; 1H; CHarom), 7.60 (m; 3H; CHarom). 13C–NMR: (100 MHz, C2D6CO): δ (ppm) = 28.2 (1C; CH2), 36.0 (1C; CH2), 42.0
(1C; CH2), 96.7 (1C; C-OH), 123.5 (1C; CHarom), 123.5 (1C; CHarom), 129.9 (1C;
CHarom), 132.9 (1C; Cq), 133.0 (1C; CHarom), 149.3 (1C; Cq), 170.0 (1C; C=O).
281
CAS No.: 162971-82-6
Experiment 151
9b-hydroxy-1, 2, 3, 9b-tetrahydro-pyrrolo[2,1-a]isoindol-5-one (102) (SG-146)
N
O
HO
C11H11NO2Mol. Wt.: 189.21 g/mol
General procedure (K) was followed, with slight variation of using the starting
materials in a ratio of 1:1 instead of the usual 2:1, using 99b (0.4 g, 1.52 mmol) and
K2CO3 (0.2 g, 1.55 mmol). After 2 hr the TLC showed the product was formed. The
solution was clear and yellow at this point. The product was found to be a light
brown powder and the 1H-NMR obtained confirmed this was the pure product. The
yield was found to be 0.1 g (0.64 mmol, 42%). The reaction was stopped after 2 hr to
prevent any unwanted side reactions from occurring, however due to the low yield a
longer irradiation time appears necessary.
1H–NMR: (400 MHz, C2D6CO): δ (ppm) = 1.50 (m; 1H; CH2), 2.30 (m; 2H; CH2),
2.57 (m; 1H; CH2), 3.35 (m; 1H; CH2), 3.60 (m; 1H; CH2), 7.50 (m; 1H; CHarom),
7.60 (m; 3H; CHarom). 13C–NMR: (100 MHz, C2D6CO): δ (ppm) = 28.2 (1C; CH2), 36.0 (1C; CH2), 41.9
(1C; CH2), 96.6 (1C; C-OH), 123.4 (1C; CHarom), 123.5 (1C; CHarom), 129.8 (1C;
CHarom), 132.8 (1C; Cq), 133.0 (1C; CHarom), 149.4 (1C; Cq), 169.9 (1C; C=O).
7.5.5 General Procedure (J2):
The desired phthalimide (0.75 mmol), was dissolved in 10 ml of acetone and K2CO3
(0.38 mmol), was dissolved in 10 ml of distilled H2O. These two solutions were
sonicated separately before being mixed together. These solutions were then added
282
together in a conical flask and made up to 50 ml using a mixture of acetone/water
(50:50). The reaction was then carried out as in general procedure (J).
Experiment 152
Comparison of Experiment 150
9b-hydroxy-1, 2, 3, 9b-tetrahydro-pyrrolo[2,1-a]isoindol-5-one (102) (SG-162)
N
O
HO
C11H11NO2Mol. Wt.: 189.21 g/mol
General procedure (J2) was followed using 99a (0.2 g, 0.75 mmol) and K2CO3 (0.1
g, 0.43 mmol). The flow rate used was 0.080 ml/min; residence time: 21 min. The
product was found to be a light brown oily solid and the 1H-NMR showed the desired
product was present and pure. The yield was found to be 0.02 g (0.09 mmol; 60%).
For 1H-NMR data see experiment 150.
Experiment 153
Comparison of Experiment 151
9b-hydroxy-1, 2, 3, 9b-tetrahydro-pyrrolo[2,1-a]isoindol-5-one (102) (SG-163)
N
O
HO
C11H11NO2Mol. Wt.: 189.21 g/mol
General procedure (J2) was followed, with the slight variation of using a ratio of 1:1
for the reagents, using 99b (0.2 g, 0.76 mmol), and K2CO3 (0.1 g, 0.80 mmol). The
flow rate used was 0.080 ml/min; residence time: 21 min. The crude material was
found to be an orange solid and the 1H-NMR showed the product was present and
pure. The yield was found to be 0.01 g (0.05 mmol; 33%).
283
For 1H-NMR data see experiment 151.
Experiment 154
9b-hydroxy-1, 2, 3, 9b-tetrahydro-pyrrolo[2,1-a]isoindol-5-one (102) (SG-166)
N
O
HO
C11H11NO2Mol. Wt.: 189.21 g/mol
General procedure (K) was followed using 99a (0.4 g; 1.52 mmol) and K2CO3 (0.1 g;
0.77 mmol), however was only irradiated for 21 minutes in order to compare with the
microreactor results. The product was found to be a colourless solid and the 1H-NMR
obtained confirmed this was the pure product. The yield was found to be 0.2 g (0.97
mmol, 64%).
For 1H-NMR data see experiment 150.
Experiment 155
9b-hydroxy-1, 2, 3, 9b-tetrahydro-pyrrolo[2,1-a]isoindol-5-one (102) (SG-167)
N
O
HO
C11H11NO2Mol. Wt.: 189.21 g/mol
General procedure (K) was followed, with the slight variation of using a ratio of 1:1
for the reagents, using 99b (0.4 g; 1.50 mmol) and K2CO3 (0.2 g; 1.56 mmol),
however was only irradiated for 21 minutes in order to compare with the
microreactor results. The product was found to be a light brown solid and the 1H-
NMR obtained confirmed this was the pure product. The yield was found to be 0.05
g (0.25 mmol, 17%).
284
For 1H-NMR data see experiment 151.
Experiment 156
(103) (SG-224)
NO
HN
O
HO
H3C
C17H14N2O3Mol. Wt.: 294.3 g/mol
General procedure (K) was followed, with the slight variation of halving the amounts
used and performing the reaction in a 50 ml Schlenk flask, using 100b (0.29 g, 0.87
mmol) and K2CO3 (0.06 g, (0.44 mmol). After 4 hr the TLC showed the product was
formed. The product was found to be a pale yellow solid and the 1H-NMR obtained
confirmed this was the pure product. The yield was found to be 0.10 g (0.35 mmol,
40%).
1H–NMR: (400 MHz, C2D6CO): δ (ppm) = 1.50 (d; 3J = 7.2Hz; 3H; CH3), 3.68 (m;
1H; CH), 6.96 (s; 1H; OH), 7.39 (m; 2H; CHarom), 7.48 (br.d; 3J = 5.6Hz; 1H; NH),
7.58 (ddd; 3J = 7.6Hz; 4J = 1.2Hz; 1H; CHarom), 7.63 (m; 1H; CHarom), 7.67 (ddd; 3J =
7.6Hz; 4J = 1.2Hz; 1H; CHarom), 7.75 (m; 2H; CHarom), 8.57 (m; 1H; CHarom). 13C–NMR: (100 MHz, C2D6CO): δ (ppm) = 15.3 (1C; CH3), 54.4 (1C; CH), 97.5
(1C; COH), 123.4 (1C; CHarom), 125.6 (1C; CHarom), 129.4 (1C; CHarom), 129.9 (1C;
CHarom), 130.1 (1C; CHarom), 131.4 (1C; CHarom), 132.2 (1C; CHarom), 132.8 (1C;
CHarom), 133.4 (1C; Cq), 135.3 (1C; Cq), 135.5 (1C; Cq), 144.5 (1C; Cq), 167.8 (1C;
C=O), 169.7 (1C; C=O).
Literature reference No.: [154]
CAS No.: 331814-59-6
285
Experiment 157
(104) (SG-157)
NO
HN
O
HO
C20H20N2O3Mol. Wt.: 336.38 g/mol
General procedure (K) was followed, with the slight variation of smaller amounts
being used as not enough acid was available, using 99b (0.37 g, 0.97 mmol) and
K2CO3 (0.25 g, 1.81 mmol) (calculation error). After 2.5 hr the TLC showed the
product was formed. The product was found to be a brown crystalline solid and the 1H-NMR obtained confirmed the product was formed; however a small amount of
side product was also present. The yield was found to be 0.19 g (0.56 mmol, 58%).
1H–NMR: (400 MHz, C2D6CO): δ (ppm) = 0.83 (d; 3J = 6.4Hz; 3H; CH3), 0.98 (d; 3J = 6.4Hz; 3H; CH3), 1.81 (m; 1H; CH), 3.68 (m; 1H; CHasym) 6.08 (s; 1H; OH),
6.89 (d; 3J = 5.4Hz; 1H; NH), 7.38 (dd; 3J = 8.0Hz; 4J = 1.2Hz; 1H; CHarom), 7.59
(ddd; 3J = 7.6Hz; 4J = 1.2Hz; 1H; CHarom), 7.62 (ddd; 3J = 7.2Hz; 4J = 1.2Hz; 1H;
CHarom), 7.68 (ddd; 3J = 7.2Hz; 4J = 1.2Hz; 1H; CHarom), 7.74 (m; 3H; CHarom), 7.78
(dd; 3J = 7.6Hz; 4J = 1.6Hz; 1H; CHarom). 13C–NMR: (100 MHz, C2D6CO): δ (ppm) = 21.3 (1C; CH3), 23.9 (1C; CH3), 26.0
(1C; CH), 38.8 (1C; CH2), 57.8 (1C; CH), 97.5 (1C; COH), 123.8 (1C; CHarom),
126.0 (1C; CHarom), 130.0 (1C; CHarom), 130.2 (1C; CHarom), 130.6 (1C; CHarom),
132.0 (1C; CHarom), 132.7 (1C; CHarom), 133.2 (1C; CHarom), 133.9 (1C; Cq), 135.6
(1C; Cq), 135.8 (1C; Cq), 144.7 (1C; Cq), 168.2 (1C; C=O), 170.4 (1C; C=O).
Literature reference No.: [154]
CAS No.: 331814-61-0
286
Experiment 158
Comparison of experiment 156
(103) (SG-221)
NO
HN
O
HO
H3C
C17H14N2O3Mol. Wt.: 294.3 g/mol
The general procedure (J2) was followed, with the slight variation of halving the
amounts used and diluting to 25 ml, using 100b (0.15 g, 0.43 mmol) and K2CO3
(0.03 g, 0.19 mmol). The flow rate was set at 0.01 ml/min; residence time: 2 hr 48
min. The 1H-NMR showed the product was formed (both isomers were present in a
ratio of 81:19) and the yield was found to be 0.02 g (0.06 mmol; 35%).
For 1H-NMR data see experiment 156.
Experiment 159
Comparison of experiment 157
(104) (SG-200)
NO
HN
O
HO
C20H20N2O3Mol. Wt.: 336.38 g/mol
The general procedure (J2) was followed, with the slight variation of halving the
amounts used and diluting to 25 ml, using 101b (0.14 g, 0.38 mmol) and K2CO3
287
(0.03 g, 0.19 mmol). The flow rate was set at 0.03 ml/min; residence time: 56 min.
The 1H-NMR showed the product was formed in a yield of 0.04 g (0.13 mmol; 87%).
For 1H-NMR data see experiment 157.
288
References
289
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Appendix